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Universidade de São Paulo Escola Superior de Agricultura “Luiz de Queiroz”
Investments in timberland: investors’ strategies and economic
perspective in Brazil
Bruno Kanieski da Silva
Dissertação apresentada para obtenção do título de
Mestre em Ciências, Programa: Recursos
Florestais. Opção em: Silvicultura e Manejo
Florestal
Piracicaba 2013
Bruno Kanieski da Silva Forest Engineer
Investments in timberland: investors’ strategies and economic perspective in Brazil
Orientador: Prof. Dr. LUIZ CARLOS ESTRAVIZ RODRIGUEZ
Dissertação apresentada para obtenção do título
de Mestre em Ciências, Programa: Recursos
Florestais. Opção em: Silvicultura e Manejo
Florestal
Piracicaba 2013
3
ACKNOWLEDGMENTS
I am very grateful to my wife Maria Eugenia Escanferla. Without her love and
partnership it would not have been possible to accomplish this project.
I wish to give thanks:
To my father, Narciso, and my mother, Janete, who always supported and
encouraged me to follow only and nothing less than my dreams.
To my siblings, Vitor and Tatiane for their support and friendship.
To my advisor, Prof. Dr. Luiz Carlos Estraviz Rodrigues, who taught and
guided me during the research
To Silvana Nobre and Mauro Assis, for the opportunities and support for the
project
To John Welker, Chris Singleton and all employees from the American Forest
Management in Sumter, South Carolina, USA.
To my co-advisor Professor Fred Cubbage from the North Carolina State
University
To all the respondents and the data providers. Their contribution made this
research possible and important for the forest sector.
To my friends from Centro de Métodos Quantitativos at Escola Superior de
Agricultura “Luiz de Queiroz”.
To my old fellows from Curitiba who make our annual meetings overcome the
distance between us.
To the Conselho Nacional de Desenvolvimento Ciêntífico e Tecnológico for
the scholarship and financial support
To Antonio Bianchi, my English teacher, for the friendship and for the effort
during the text review.
To the staff of the Universidade Estadual de São Paulo.
To everyone, thank you very much
Bruno Kanieski da Silva
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“ No que diz respeito ao empenho, ao
compromisso, ao esforço, à
dedicação não existe meio termo. Ou
você faz uma coisa bem feita ou não
faz”
Ayrton Senna
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6
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CONTENTS
ABSTRACT ............................................................................................................... 11
RESUMO ................................................................................................................... 13
1 INTRODUCTION ................................................................................................ 15
1.1 PLANTED FORESTS IN THE WORLD ..................................................................... 15
1.2 PLANTED FORESTS: FUTURE TREND ................................................................... 16
1.3 PLANTED FORESTS AS INVESTMENT .................................................................... 17
1.4 BRAZILIAN FOREST SECTOR ............................................................................... 18
1.5 THESIS PURPOSE AND STRUCTURE ..................................................................... 21
BIBLIOGRAPHY ......................................................................................................... 22
2 TIMBERLAND INVESTMENT MANAGEMENT ORGANIZATION (TIMO)
STRATEGIES FOR FOREST PLANTATION INVESTMENT IN BRAZIL .................. 25
ABSTRACT ............................................................................................................... 25
RESUMO .................................................................................................................. 26
2.1 INTRODUCTION .................................................................................................. 27
2.1.2 TIMOs and forest investments................................................................... 28
2.1.4 Research Focus ........................................................................................ 30
2.2 METHODOLOGY ................................................................................................. 31
2.2.2 Research design ....................................................................................... 31
2.2.2 The Cluster analysis .................................................................................. 32
2.2.3 Dataset ...................................................................................................... 33
2.2.4 The Cluster Method ................................................................................. 35
2.2.4.1 Software R .......................................................................................... 35
2.2.4.2 The Cluster analysis ........................................................................... 35
2.2.6 Hierarchical Algorithms ............................................................................. 36
2.2 RESULTS .......................................................................................................... 37
2.3.1 Participants ............................................................................................... 37
2.3.2 Background Information ............................................................................ 37
2.3.3 General Analysis ....................................................................................... 39
2.3.4 Broad Factor Analysis ............................................................................... 41
2.2.5 Investment decision ................................................................................. 42
2.3.5.1 Macroeconomics ................................................................................. 42
2.3.5.2 Institutional.......................................................................................... 45
2.3.5.3 Forest ................................................................................................. 47
2.2.6 Cluster Analysis ....................................................................................... 49
2.2.6.1 Variables Analysis: ........................................................................... 49
2.2.7 Minimum Acceptable Rate of Return ....................................................... 52
2.2.8 Investors’ Perceptions ............................................................................. 54
2.4 DISCUSSION ....................................................................................................... 55
2.5 CONCLUSION...................................................................................................... 57
2.6 BIBLIOGRAPHY ................................................................................................... 59
8
3 THE ECONOMIC COMPETITIVENESS AMONG TRADITIONAL REGIONS AND
NEW AGRICULTURAL FRONTIERS IN FOREST INVESTMENTS IN BRAZIL. ...... 64
ABSTRACT .............................................................................................................. 64
RESUMO ................................................................................................................. 65
3.1 INTRODUCTION .................................................................................................. 66
3.1.1 The forest sector in traditional regions in Brazil ........................................ 66
3.1.2 Business Environment .............................................................................. 67
3.1.3 Forest Sector Investment Expansions ...................................................... 68
3.1.4 Land Market in Brazil ................................................................................ 69
3.1.5 Resource Focus........................................................................................ 72
3.2 METHODOLOGY ................................................................................................. 73
3.2.1 Study sites ................................................................................................ 73
3.2.1.1 São Paulo State ................................................................................. 74
3.2.1.2 Mato Grosso do Sul State .................................................................. 75
3.2.1.3 MAPITO region .................................................................................. 76
3.2.2 Land price historic..................................................................................... 76
3.2.3 Financial criteria for investments in forest projects ................................... 77
3.2.3.1 Net Present Value .......................................................................... 78
3.2.3.1 Internal Rate of Return ................................................................... 78
3.2.3.2 Land Expectation Value .................................................................. 79
3.2.3.3 Willingness to Pay for Land, considering future land value ............ 79
3.2.4 Revenues ................................................................................................. 80
3.2.4.1 Stumpage price .................................................................................. 80
3.2.4.2 Volume Estimation ............................................................................. 80
3.2.5 Costs ........................................................................................................ 82
3.2.5.1 São Paulo State ............................................................................... 82
3.2.5.1.1 Labor Cost ................................................................................... 83
3.2.5.1.2 Machinery Costs .......................................................................... 84
3.2.5.2.1 Fixed Costs .............................................................................. 84
3.2.5.2.1.1 Depreciation Cost .............................................................. 84
3.2.5.2.1.2 Opportunity Cost................................................................ 85
3.2.5.2.1.3 Taxes, insurance, housing (TIH) ....................................... 86
3.2.5.2.1.4 Variables Costs ................................................................. 86
3.2.5.2 MAPITO and Mato Grosso do Sul State ............................................ 87
3.2.5.3 Land Price .......................................................................................... 88
3.2.5.3.1 Land Opportunity Cost ................................................................. 88
3.2.5.3.1 Land price speculation scenarios ................................................ 89
3.2.6 Monte Carlo Method ................................................................................. 89
3.2.6.1 Input Statistical Distributions .............................................................. 89
3.2.6.2 Maximum Likelihood Estimators (MLEs) ............................................ 90
3.2.6 .3 Chi – Square test ............................................................................. 90
3.2.7 Sensitive Analysis ..................................................................................... 91
3.3 RESULTS AND DISCUSSION................................................................................. 92
9
3.3.1 Revenues .................................................................................................. 92
3.3.1.1 Yield models ....................................................................................... 92
3.3.2 Cost ........................................................................................................... 95
3.3.2.1 Silvicultural Operations ....................................................................... 95
3.3.3 Financial criteria ........................................................................................ 99
3.3.3.1 Net Present Value (NPV) .................................................................... 99
3.3.3.3 Land Expected Value (LEV) ........................................................... 101
3.3.3.3.1 General Analysis ........................................................................ 101
3.3.3.3.2 Land Bid Prices .......................................................................... 103
3.3.3.4 Willingness to Pay for Land (WPL), considering future land value .... 104
3.3.3.4.1 Land price will increase in real terms: ........................................ 104
3.3.3.4.2 Land price will keep the same level in real terms ....................... 105
3.3.3.4.3 Land price will decrease annually at the same rate as the average
of the negative rates observed in each region in the last 10 years. .......... 106
3.3.4 Sensitive Analysis. .................................................................................. 108
3.3.4.1 Net Present Value (NPV) .................................................................. 108
3.3.4.2 Internal Rate of Return (IRR) ............................................................ 110
3.3.4.4 Willingness to Pay for Land, Considering Future Land Value ........... 113
3.3.4.4.1 Land price will increase in real terms. ........................................ 113
3.3.4.4.2 Land price will keep at the same price in real terms. .................. 114
3.3.4.4.3 Land price will decrease annually following the same average rate
as the negative rates. ................................................................................ 115
3.3.4.4.4 Expected Valuation Analysis ...................................................... 118
3.4 DISCUSSION ..................................................................................................... 118
3.4.1 Land cost effect ....................................................................................... 119
3.5 CONCLUSION.................................................................................................... 121
BIBLIOGRAPHY ....................................................................................................... 122
APPENDIX ........................................................................................................... 129
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ABSTRACT
Investments in timberland: investors’ strategies and economic perspectives in Brazil
Forest plantations provide essential services for human beings. More recently,
population and economic growth have increasingly intensified the demand for forest
products. Forest activities are expanding to new areas due to low land prices and
governmental incentives in Brazil. Among others; Timberland Investment
Management Organizations (TIMOs) are a type of invertors that have significantly
increased their participation in the timberland market. The purpose of this thesis is to
investigate investor’s strategies and the mains aspects related to forest investments
in Brazil. The thesis is divided into two chapters. The first chapter investigates
strategies used by TIMOs in Brazil and their declared expectations on returns. The
second chapter offers a comprehensive analysis of the level and variability of the
return rate for three different regions in Brazil.
Keywords: Forest asset analysis; Project assessment; Timberland prices; TIMO;
Investment analysis; Risk; Return rate.
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13
RESUMO
Investimentos em ativos florestais no Brasil: estratégias dos investidores e
perpectivas econômicas
As plantações florestais fornecem serviços vitais para os seres humanos.
Devido ao crescimento populacional e econômico, a demanda por produtos oriundos
de florestas plantadas cresceu rapidamente nos últimos anos.Entre os países que
possuem uma forte base florestal, Brasil ocupa um papel essencial como produtor
de florestas plantadas. A disponibilidade de terra e a alta produtividade atraíram
diversos tipos de investidores para o país. As Timberland Investment Management
Organization (TIMOs) estão entre os tipos de investidores ampliou seus
investmentos no mercado florestal brasileiro. Em paralelo, o setor florestal brasileiro
tem expandido para novas áreas devido ao menor custo da terra e incentivos
governamentais. Essa dissertação tem como principal objetivo investigar as
estratégias e espectativas dos investidores estrangeiros e os principais aspectos
relacionados a projetos florestais no Brasil. A dissertação está dividida em dois
capítulo. O primeiro capítulo investiga as principais estratégias e os retornos
esperados das TIMOs em investimentos florestais no país. O segundo capítulo
analiza os níveis de atratividade e seus retornos em três diferentes regiões do país.
Palavras chaves: Análise de ativos florestais; Avaliação de projetos; Preço de terra
florestal; TIMO; Análise de investimento; Risco; Taxa de retorno.
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1 INTRODUCTION
1.1 Planted Forests in the World
A planted forest is defined by the Food and Agricultural Organization of the
United Nations (FAO) (2011) as:
“legitimate land use to provide wood, fiber, fuel, and non-wood, forest products,
addressing industrial round wood demand and sustainable livelihoods, ensuring food
security and contributing to poverty alleviation”.
Planted forests, therefore, play an important role in the society by providing
basic services to humans. The establishment of planted forests has provided
economic and social benefits for communities and countries namely land use
optimization and reduction of intervention in natural areas to log wood and nonwood
products. Furthermore, according to the Intergovernmental Panel on Climate Change
planted forests have proven to be some of the most efficient ways to sequestrate
CO2 due to their high productivity level (NABUURS, et al, 2007)
The total afforested areas worldwide covered approximately 4 billion hectares in
2010 (FAO, 2010) while forest plantations covered 263 million hectares, from which,
200 million hectares are allocated for wood production the other 64 million hectares
are used for conservation purposes.
Table 1.1 Planted forest areas distribution by continent
Region Area of planted forests
1000 ha % of total forest area
World 264,084.00 100
Asia 122,775.00 46.49
Europe 69,318.00 26.24
North and Central America 38,661.00 14.63
Africa 15,409.00 5.83
South America 13,282.00 5.02
Oceania 4,101.00 1.50
Source: FAO, 2010
The planted forests area is expected to expand and occupy new regions in the
upcoming years. Abandoned marginal pastures and agricultural lands have been
16
replaced by forest plantations in developing countries (BREMER; FARLEY, 2010).
Moreover, the wood market is promising and demand for timber products is likely to
increase in the next years (INCE et al., 2012).
1.2 Planted Forests: Future trend
As planted forests derivatives replace products from natural forests and world
demand for wood increases, planted forests production tends to grow. According to
(FAO, 2009) demand for wood in the society is stimulated by the following factors: (1)
population growth, (2) economic growth, (3) the increasing consumption by
developing countries, (4) environmental policies for forest preservation and (5)
forests as energy source. The combination of these factors has pushed up wood
consumption.
Between 1990 and 2005, wood consumption increased 6.5 % (FAO, 2009). This
figure does not include consumption for energy, which would have a large
significance due to European policies to promote the replacement of nonrenewable
to renewable energy sources and the increasing demand for biomass from Asia
(DEMIRBAS, 2008; KATSIGRIS et al., 2004).
Forecasts of wood consumption are constantly performed to help government
and business leaders’ strategies and provide information about the timber production.
The outlook of forest plantation has been constantly discussed in the last decade
(ABARE, 1999; CARLE; HOLMGREN, 2008 and FAO, 2000).
Carle & Holmgren (2008) published the most recent research about future wood
production. The authors modeled the world wood supply from 2005 to 2030 in three
scenarios: (1) pessimist: the current increase of planted forests will slow down and
the productivity will not increase, (2) business as usual: the current increase of
planted forests will continue at the same rate; however and the productivity will
increase and (3) optimist: the same as in scenario 2, but the productivity will
increase. The authors state that the total planted area is estimated to reach from 302
to 344.6 million hectares. It represents an increase from 15 % to 30 % in relation to
the current area or an area approximately as large as Spain (50. 6 million hectares).
In terms of production, until 2030, wood supply may increase from 1,400 million
cubic meters to a range between 1,590 to 2,150 million cubic meters, i.e., 13 % to 53
% more than the current production (Carle & Holmgren, 2008). To better visualize the
17
scenarios, the volume of planted forests added in the pessimist scenario (190 million
cubic meters) would be enough to supply the Brazilian pulp and paper industry for 5
years1.
The increase in volume also affects the wood market directly. The global timber
market moved 468 billion dollars in 2006, which meant an increase of 10 % in
relation to 1990 (424 billion dollars) (FAO, 2009). The wood market has attracted
different investors and thereby increasing competition and dynamism.
1.3 Planted Forests as Investment
The first planted forest were funded and supported by government initiatives;
large areas were then planted for wood supply and research purposes. Since then,
the forest sector have increased significantly worldwide, private funds and direct
foreign investments have become as important as the incentives provided by the
governments. Consequently, the planted forest sector became a market oriented
investments, which the main players are the vertically integrated companies,
individuals and institutions , as well as the government (FAO, 2010).
Over the last 30 years a new perspective of forest use has been adopted by the
economic structure; timberlands have become part of a portfolio as an asset
(SWITZER, 2006; ZHANG et al., 2012). This trend was more noticeable in the U.S.,
where institutions have purchased large areas of timberland.
Timberland investments became attractive for institutions due to the following
characteristics: (i) the inherent inflation hedge, (ii) low or/and negative correlation
with other assets in the investor’s portfolio (iii) the historical profits investments in
timberland generates and (iv) the low risk involved in the investment (HEALEY et al.,
2005; SWITZER, 2006).
Institutional investors started to purchase and manage timberlands to maximize
profits and minimize risks. HEALEY et al.( 2005) affirmed that if 10 % of their portfolio
were composed by timber, the investment returns would rise from 12 % to 14 %, at
the same risk level.
1 As reported the Brazilian Pulp and Paper Association (BRACELPA), the Pulp and Paper Sector
consumed 26 million tons of Eucalyptus and 5 million tons of Pine tree in 2012. The conversion to
cubic meter used was 1.04 for Pine tree and 1.15 for Eucalyptus according to SBS,2008.
18
These benefits encouraged institutions to acquire timberlands. While in 2005,
they owned approximately 22 billion dollars (SWITZER, 2006), in 2011, the
investment achieved 50 billion dollars (FAO, 2012). In order to manage the economic
returns from timberland assets, two groups of professional investors were created: (i)
Timberland Investment Management Organization (TIMO) and (ii) Real Estate
Investment Trust (REIT).
TIMOs manage timberland portfolios to maximize their financial returns. They
analyze business opportunities and investments in productive timberlands. By the
TIMOs, investors become owners of the land and their profit come from real estate
speculation and timber production. REITs have the same purpose as TIMOs;
however, they have a different structure. REITs have tax advantages that are linked
to the real estate trust market in the U.S.A. Besides, REIT works similarly to bound
markets, from which any investor can buy shares in a public traded REIT. Therefore,
REIT has more liquidity than TIMO.
REITs and TIMOs are on the rise in the U.S. and worldwide. Their structure
makes it easier for an investor to get into the forest business. Furthermore,
timberland has attracted investors to most productive forest countries in the world,
namely Brazil, Chile, Canada, Uruguay, Central America, Australia, New Zealand
and Eastern Europe (FAO, 2012). Among these countries, Brazil has shown
promising characteristics.
1.4 Brazilian Forest Sector
Although Brazil has only 6.5 million hectares covered with forest plantations (2.8
% of the total planted forest in the world) (ABRAF, 2012), the country has an
important role in the forest production sector. High wood productivity, land availability
and relative low cost assigned the country among the most promising forest
producers. The area covered with forest plantations in Brazil increased 30 %
between 2005 and 2010, while China, USA and Russia increased 14 %, 4 % and 0.7
%, respectively, during the same period (Graph 1.1).
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Graph 1.1Planted forest in the world. Source: FAOSTAT - FAO, 2010
The planted forest production in Brazil increased 145 % (47 million to 115
million cubic meters) between 1990 and 2010 according to the Brazilian Institute of
Geography and Statistics (IBGE). The production demonstrates a linear growth with
an annual increase of 5.5 % (Graph 1.3).
Graph 1.2 Wood log productions in Brazil. Source: SIDRA - IBGE,2010.
In 2010, wood production from the pulp and paper sector amounted 69 million
cubic meters, while, the volume produced for sawmill and chipping industries
reached 45 million cubic meters. The difference in volume produced is related to the
investment in the sector; once, 10 billion dollars was invested in pulp and paper over
the last 10 years, as reported the BRACELPA (2012). Furthermore, demand from the
international market increased sharply in recent years, mainly from China. In 2000,
39.5 % of cellulose production in Brazil was exported, while in 2009, exports totaled
62.9 % (MONTEBELLO; BACHA, 2011). Additionally, the international and national
demands for fuel wood increased over the last years. Fuel wood production will gain
a significant role in the wood production in the next years in Brazil.
20
Due to the presence of larger markets, forest production is concentrated in the
Southern and Southeastern regions of Brazil (Graph 1.3).Altogether, these regions
account for 78 % of the total production in the country (91 million cubic meters)
(IBGE, 2010).
Graph 1.3 Wood productions in Brazil. Source: SIDRA - IBGE, 2010.
Most success of Brazilian plantations are credited to the biological growth of
trees and to a strong internal wood market. On average, the tree growth rate is 41
cubic meters per year for Eucalyptus and 37 cubic meters per year for Pine. Trees in
Brazil grow 30 % more than any place in the world (ABRAF, 2012).
The perspectives for new investments in timberland in the country are high. The
Brazilian government and investors are exploring new regions and promoting the
establishment of new-planted areas. Macroeconomic perspectives and domestic
demand for wood products have attracted investors throughout the world to invest in
the Brazilian planted forests.
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1.5 Thesis purpose and structure
Timberland is one of the most attractive assets in the current economy scenario.
The macroeconomic scenario encourages a range of investors to acquire and
manage forest assets in order to maximize returns and minimized risks in their
portfolio. To achieve success, investors must be aware about factors that influence
forest investments. Moreover, the globalization of the forest assets has created new
opportunities and made the market more competitive. On the one hand, governments
want to attract investors to their country by creating a desirable environment for
businesses, and, on the other hand, investors are seeking for more profitable and
safe environments for their investments. These combinations have increased the
competition among countries and among investors. South America, especially Brazil,
is one of the most promising regions to invest in timberland.
The purpose of this research is to analyze the strategies of timberland investors
and timberland investment as a whole. To achieve this goal, the thesis is divided into
two chapters: (1) Timberland Investment Management Organization (TIMO)
strategies for forest plantations investments in Brazil and in the U.S.A. and (2) The
economic competitiveness among traditional regions and new agricultural frontiers in
forest investments in Brazil.
In the first chapter, we prepared a survey covering the main aspects regarding
timberland investments and applied it to the main American TIMOs, which, either
current have investments in Brazil or are looking for opportunities in the country.
The second chapter approaches the influence of land price on timberland
investment in Brazil. Based on an assessment of production costs, we performed
cash flow analyses to understand the factors that are making new agricultural
frontiers in Brazil more attractive than others for forest investors.
22
BIBLIOGRAPHY
ABARE. Global Outlook for Plantations. Canberra : ABARE,1999. 76 p. Australian
Bureau of Agricultural and Resource Economics Research (Report 99.9.)
ABRAF. Anuário Estatístico da ABRAF. Brasília: ABRAF,2012.76 p. Reporte anual
da Associação Brasileira dos Produtores de Florestas Plantadas.
BRACELPA. Dados do Setor. São Paulo:BRACELPA,2012. 3p. Associação
Brasileira de Celulose e Papel – Dados sobre o Setor.
BREMER, L.L.; FARLEY, K.A. Does plantation forest restore biodiversity or create
green deserts? A synthesis of the effects of land-use transitions on plant species
richness. Biodiversity and Conservation, Dordrecht, v. 19, n. 14, p. 3893-3915,
2010.
CARLE, B.J.; HOLMGREN, P. Wood from a Global Outlook 2005-2030. Forest
Product Journal, Madison, v. 58, n. 10469, p. 6-18, March 2008.
DEMIRBAS, A. Biofuels sources, biofuel policy, biofuel economy and global biofuel
projections. Energy Conversion and Management, Amsterdam, v. 49, n. 8,
p. 2106-2116, Aug. 2008.
FOOD AND AGRICULTURE ORGANIZATION OF THE UNITED NATIONS. FAO
Data Base. FAOSTAT: The Statistical Data Base of the FAO. Available at<
http://faostat.fao.org/?lang=en>, Accessed at January 11th of 2013.
FAO. The global outlook for future wood supply from forest plantations. Working
paper series, Rome: v.1, n.3,2000. Available at :
<http://www.fao.org/docrep/003/X8423E/X8423E00.HTM>. Accessed in: 10 Jan.
2013.
FAO. State of the World’s Forest.Rome:FAO,2009. 63 p. World’s forest report.
FAO. Global Forest Resources Assessment. Rome:FAO,2010. 86 p. Report about
the Global Forest Resources.
23
FAO. Timberland in Institutional Investment Portfolios : Can Significant Investment
Reach Emerging Markets ? Forestry Policy and Institutional Working Paper.
Rome,v.1, n. 31, 2012. Available at: <http://www.fao.org/forestry/finance/en/>.
Accessed in: 05 Jan.2013.
HEALEY, T.; CORRIERO, T.; ROZENOV, R. Timber as an Institutional Investment.
The Journal of Alternative Investments, New York, v. 8, n.3 p. 60-76, July 2005.
INSTITUTO BRASILEIRO DE ESTATÍSTICA E GEOGRAFIA. Sistema IBGE de
Recuperação Automática. SIDRA: Banco de dados integrados do IBGE. Available
at< http://www.sidra.ibge.gov.br/>, Accessed in :11 jan. 2013.
INCE, P.J.; KRAMP, A.; SKOG, K.E. Evaluating Economic Impacts of Expanded
Global Wood Energy Consumption with the USFPM/GFPM Model. Canadian
Journal of Agricultural Economics/Revue canadienne d’agroeconomie, Quebec,
v. 60, n. 2, p. 211-237, June 2012.
KATSIGRIS, E.; BULL, G.Q.; WHITE, A. BARR, C.; BARNEY, K.; BUN,Y.;KAHRL,
F.; LANKIN, A.; LEBEDEV, A.; SHEARMAN, P.; SHEINGAUZ, A.; YUFAN, S.;
WEYEARHAUESER, H.The China Forest Products Trade: Overview of Asia-Pacific
Supplying Countries, Impacts and Implications. International Forestry Review,
Abingdon,v. 6, n. 3/4, p. 237-253, Dec. 2004.
MONTEBELLO, A.E.S.; BACHA, C.J.C.B. O setor de celulose e papel na economia
brasileira. O Papel,São Paulo, v. 72, n. 4, p. 47-50, 2011.
SWITZER, T. Money does grow on trees. National Real Estate Investor, Chicago,
v. 48, n. 5, p. 98-103, Mar.2006.
ZHANG, D.; BUTLER, B.; NAGUBADI, R. Institutional Timberland Ownership in the
US South: Magnitude, Location, Dynamics and Management. Journal of Forestry,
Bethesda, v. 4, n. , p. 355-361, Nov.2012.
NABUURS, G.J.; MASERA, O.; ANDRASKO, K.; BENITEZ-PONCE,P.; BOER,R.;
DUTSCHKE,M.; ELSIDDIG,E.;FORD-ROBERTSON,J.; FRUMHOFF,
P.;KARJALAINEN,T.; KRANKINA O.;KURZ, W.;MATSUMOTO, M.;
24
OYHANTCABAL,W.; RAVINDRANATH,H.; SANZ SANCHEZ,M.; ZHANG,
X.Forestry. Climate Change 2007: Mitigation. Contribution of Working Group III to
the Fourth Assessment Report of the Intergovernmental Panel on Climate Change ,
New York: Cambridge University Press, 2007, chap. 9, p. 543-578.
25
2 TIMBERLAND INVESTMENT MANAGEMENT ORGANIZATION (TIMO)
STRATEGIES FOR FOREST PLANTATION INVESTMENT IN BRAZIL
Abstract
Timberland investments have become popular among institutional investors in
the last decades. The long term, relative low risk and reasonable returns of
investments are among the features that have encouraged institutional investors to
include timberland asset in their portfolio. Among other investors, Timberland
Investment Management Organization (TIMO) has had a meaningful expansion.
TIMOs aim to maximize financial returns to their clients (pension funds, insurance
and financial institutes) by purchasing and selling timberland and providing their
services. They began their business in the U.S.A. and, they are currently investing in
all standard forest producing countries. Brazil stands out as one of the most attractive
countries for timberland investments in the world. The purpose of this chapter is to
analyze TIMOs strategies and preferences regarding new international timberland
investments. We elaborated an open-ended survey covering the key aspects that
affect the decision-making process of international investor in timberland. We applied
the survey to the American TIMOs that current have or intend to have timberland
assets in Brazil. Moreover, we performed a cluster analysis to identify different
groups macroeconomic, institutional and forest aspects analyzed. The TIMOs
presented different strategies in forest asset investments. As expected, the surveys
show that returns and risks are the most crucial aspects for investments; however,
political risks, land prices and personal security might be crucial to some
respondents. The cluster analysis identified two distinguished groups among for
aspect proposed. One includes the aspects related to economic perspective and
another to institutional perspective. The TIMOs are still willing to invest in Brazil; the
country presents several desirable characteristics; nevertheless, the infrastructure
and political risks such as the Codigo Florestal and land acquisition from foreign
investors delay or inhibit some TIMOs investors.
Keywords: Business strategies; Cluster analysis; International investments, Financial
returns, Forest asset investments.
26
Resumo
O investimento em ativos florestais tornou-se popular entre os investidores
institucionais nas últimas décadas.Determinadas caracteristicas como longo de
horizonte, baixo risco e razoável retornos econômicos tem incentivado determinados
investidores a incluir ativos florestais em seus portifólios. As Timberland Investment
Management Organization (TIMOs) tiveram um crescimento expressivo nos últimos
anos. As TIMOs tem como objetivo maximizar os retornos economicos de seus
clientes (fundos de pensão, seguradoras, e outras instituições financeiras)
comprando e vendendo terras florestais e comercializando seus produtos. As TIMOs
iniciaram suas operações nos Estados Unidos e atualmente estão investindo em
todos os países produtores de florestas. Brazil é considerado uma das mais atrativas
regiões para se investir em ativos florestais. O objetivo desse capítulo é analizar as
estratégias e preferências das TIMOs em investmentos internacionais. Nós
elaboramos um questionário para investigar as principais influências na decisão em
investimentos internacionais em ativos florestais. Esse questionário foi respondido
por TIMOs americanas as quais possuem ou deseja futuramente investir em ativos
florestal no Brasil. Além disso, nós utilizamos técnicas de análise de agrupamento
para identificar os diferentes grupos entre os principais aspectos analisados. As
TIMOs apresentam diferentes estratégias em investimentos em ativos florestais.
Como esperado, retorno e risco foram considerados os mais importantes, entretanto,
risco político, preço de terra e risco pessoal possuem forte influências na tomada
decisão das TIMOs. A análise de cluster identificou dois grupos distintos entre os
aspectos estudados, o primeiro é composto principalmente por aspectos economicos
e o segundo por aspectos institucionais. As TIMOs tem interesse em investir no
Brazil, o país apresenta muitas características atrativas, entretanto, a infra estrutura
e o risco político, como a indecisão gerada pelo Código Florestal e a barreira na
compra de terras, por capital estrangeiro são alguns dos obstáculos que atrasam ou
inibem os investimentos das TIMOs.
Palavras - chaves: Estratégias de negócio; Análises de agrupamento; Investimentos internacionais; Retornos financeiros; Investimentos em ativos florestais.
27
2.1 Introduction
Investments in forest assets are well known as long-term alternatives with
relative low risk and attractive returns. These features have encouraged institutional
investors to manage timberland investments and consequently, diversify their
portfolio and minimize the risks (CLEMENTS et al., 2011; HAGENSTEIN, 1984;
REDMOND; CUBBAGE, F. W., 1988a).
In order to capitalize such investments, specific financial institutions called
Timberland Investment Management Organization (TIMOs) were created. TIMOs aim
to maximize the value of timberland asset by managing and commercialized their
products (BOWYER; HOWER, 2007).
By using a TIMO, the investor becomes the owner of the land and the TIMO
specialists guide them to the most profitable management strategy. TIMOs can
operate their investments by two primary models: (i) closed-end funds and (ii)
separate accounts. The closed-end funds consist of multiple investors who purchase
timberland and manage timber for a certain time. Conversely, separate accounts
consist of individual investors who purchase the timberland and manage it over an
indefinite period.
TIMOs investments were initiated in the United States and have spread their
portfolio in countries throughout the world in the last decades. They are looking for
new opportunities and places that demonstrate economic potential. Brazil is among
the most promising countries in the world in forest production. The country offers a
large extension of available land with good potential for planted forests, some of the
best plantation growth rates in the world, good access to export markets, and a high
level of technology for planted forests and manufacturing.
2.1.1 TIMO motivation
The interest in TIMOs and other types of institutional investments in the United
States has been driven by two principal events; (i) the Employee Retirement Income
Security Act (ERISA) of 1974 and (ii) the sale of timberland by the forest industry.
One of ERISA’s purpose is to guarantee employees a future amount though
pension funds (KEVILLE, 1994). For that purpose, ERISA demands a minimum
diversification in the pension fund portfolio and, thus presumably reducing the
investment risks.
28
The second reason was prompted by a major shift in forest ownership, where
most industrial timberland was transferred to institutional investors or converted to
Real Estate Investment Trust (REITs) (CLUTTER et al., 2005; HAGENSTEIN, 1984).
Several factors led to these divestitures: the weak financial performance of the forest
products industry; the need of the industry to focus on the manufacturing process;
the need to cover debt due to recent acquisitions and mergers in the industry, and
the tax policy applied to timberland industry (BLOCK; SAMPLE, 2001). As a result ,
sales of industrial timberland increased shareholder values and did not impose long-
term cost of capital financing (SUN; ZHANG, 2011).
2.1.2 TIMOs and forest investments
In 25 years, the vertically integrated companies of forest products have sold 60
% of their timberland area. In 1980, these companies held 23 million hectares (57
million acres) while, by 2005, their assets decreased to 8.5 million hectares (21
million acres) (LÖNNSTEDT; SEDJO, 2012). The major forest productive lands in the
U.S.A. have been sold to either TIMOs or other organizations or converted into
REITS.
Among the other players in the timberland market, TIMOs have played an
important role. The financial impact of TIMOs on the market has been significant. In
1985, TIMOs invested less than US$ 1 billion, while in 2005, TIMOs investments
amounted approximately $ 15 billion (MENDELL, 2006 apud LÖNNSTEDT; SEDJO,
2012).
TIMOs purchase and manage forestland depending on how attractive the
market is for certain products and services in the region, including the land use either
for recreational and hunting purposes or for the traditional management for wood
products. Such interests have driven investments at a large spectrum of forestland
types.
29
2.1.3 Foreign investments in Brazil
The rapid increase in demand and competition for acquisitions of the best
timberland has pushed land prices upward in the U.S.A., consequently, North
American TIMOs started searching for new investments overseas. Many funds have
become interested in managing international timberlands. Currently, around 0.6
million hectares are managed by TIMOs overseas, e.g., in Latin America, New
Zealand, Australia and Indonesia (MENDELL, B. C. et al., 2011).
Although economic risks and political instability may seem lower in developing
countries, the usual uncertainty observed in Latin America and Indonesia has been
overcome by the higher return rates in timberland investments observed in this
region (CUBBAGE, F. et al., 2007, 2010). Among others, Brazil has shown favorable
developments in its domestic markets and shown good economic perspectives,
becoming one of the most promising countries for forest investments in the world.
With 851 million hectares (2.1 billion acres), Brazil is the largest country in
South America and the 5th largest in the world. The country is the 6th economy in the
world, with a Gross Domestic Product (GDP) of US$ 3.67 trillion in 2010. Moreover,
several credit rating agencies have upgraded Brazil’s risk index. The Emerging
Markets Bond Index Global (EMBI +), calculated by the bank J.P. Morgan, measures
a country’s risk based on the government debt. In the last 10 years, Brazil’s index
decreased 84%. One of the most important indexes, Standard & Poor’s (S&P)
upgraded Brazil’s foreign debts from BBB minus to BBB, besides Mexico and South
America, which classifies the country with an investment grade as economically
stable for business. It is the best position of the country in its entire history.
In this promising economic scenario, forest production has an important
contribution to Brazil’s economy. The forest sector accounts for 4% of the Brazilian
GDP (SBS, 2008). The country has 516 million hectares (1.2 billion acres) occupied
by natural forest, i.e., 56% of the total area. The total area with planted forests covers
approximately 7 million hectares (17 million acres), mostly cultivated by Eucalypt and
Pine trees; 4.5 and 1.8 million hectares (11.1 and 4.4 million acres) respectively. The
areas planted with these species account for 93 % of the total planted area.
Vertically integrated companies forest products companies such as pulp and
steel mills own most timberlands. The presence of institutional investors in timberland
is relatively new in Brazil. TIMOs started to establish new plantations in 2000 by
30
planting pine in the Southern region of the country. They held approximately 100
thousand hectares (250 thousand acres) in 2005 (MENDES, 2005). According to
CONSUFOR ( 2009), in 2009 TIMOs owned 176,000 hectares (434,000 acres) of the
planted area. , an increase of 76% comparing to 2005. .
The interest of international investments in timberland in Brazil is likely to
increase in the next few years. I Timberland investments, however, are seen with
different criteria and expectations. Planted forests with both Eucalypt and Pine have
the highest returns in the world (CUBBAGE, F. et al., 2007, 2010), and timber prices
have also risen . Many regions in Brazil have aggressively recruited forest industry
and investors, offering large available land areas. These advantages are tempered
by some business hindrances and governmental uncertainty.
2.1.4 Research Focus
Despite their recent influence on the timberland market in Brazil, there is no
scientific research related to TIMOs activities published in specialized periodicals or
journals in the country. Most information available is related to how they operate and
the size of their operations (CONSUFOR, 2009; MENDES, 2005; TUOTO, 2007).
Furthermore, there is little research on the strategies adopted by TIMOs in any
country; in North America or elsewhere.
Information about TIMOs’ strategies is essential to understand how they
influence the timberland market and to define governmental actions to attract future
investors to the country. This chapter aims to redress this lack of studies on TIMOs
and initiate new studies and questions about the influence of institutional
organizations on the timberland market in Brazil.
The motivation of this research was based on the following hypothesis:
1) There are different strategies and criteria used by TIMOs in the U.S.A. for
international investments.
2) Although, there is a large potential market in Brazil, TIMO investments have not
achieved their expected size.
3) Macroeconomic, institutional and forest factors have different roles and weight
on TIMO’s decisions.
We have examined these hypotheses to explain how TIMOs choose their
investments overseas and how they build their expectations over new asset
31
acquisitions. This analysis allowed the identification of the main particularities that
have affected decisions for forest investments in Brazil.
2.2 Methodology
2.2.2 Research design
This research relied on a mixed qualitative and quantitative survey (Appendix
4.1). The survey was developed in association with Fred Cubbage, professor from
the Department of Forestry and Environmental Resources at the North Carolina State
University. The survey included questions covering the main strategic aspects about
timberland investment in Brazil and in the U.S.A. TIMOs either with current
investments or interested to invest in Brazil were invited to participate in the
research. The survey was conducted through person-to-person questions or on the
phone. Participants were notified by a consent document (Appendix 4.2) about the
approximate time required to complete the survey, dataset storage, measures and
confidentiality terms. They were not compensated by any source for answering the
survey.
As the survey involved interviews and socio-economic dataset analyses, the
authors followed standard qualitative research protocols. We developed draft
questionnaires, obtained reviews from other colleagues from the forest management
sector and professors, and then submitted the questionnaire to the North Carolina
State University research review board. The survey was approved by Institutional
Review Board (IRB) for the human participants in research at the North Carolina
State University and followed all its prescribed principles (Appendix 4.3).
The survey was adapted from the forest investments attractiveness index
elaborated by the Inter-American Development Bank (IADB, 2008) and combined
with complementary questions formulated by the authors. The survey covered four
aspects of forest investment:
1) Background information: this section covers the companies’ structure
information like current experience in forest asset investments, amount of funds
under management, location and size of the forest assets and the approach in new
investments oversea.
32
2) Investment decision: it gathers information about the TIMOs’ preferences in
forest asset investments; the relevance of macroeconomics; infrastructure; and forest
factors on the process of choosing new investments.
3) Investor preferences: it covered investors’ expectation in timberland investment
and the process to become a timberland investor.
4) Future perspectives for timber investment.
We applied open-closed questions during the interviews. We performed all the
interviews orally without any tape recording. This method was chosen to make the
individuals interviewed more comfortable, since they were addressing sensitive
corporate strategic information. We then digitally stored the tabular closed-end
questions, and wrote quotes as reliable as possible to the interview. There still was
probably lack of exactness in this method, but it was more likely to garner candid
responses and open discussion. Thus, the quotes showed in the following results
analysis may not be identical to what the interviewees said. However, they are very
close and accurate in their intent, as it will be shown in the results.
The cluster analysis approach was used in the data from the macroeconomic,
institutional and forest factors that influence investment decisions. In this approach, a
rank system was performed to understand different investors’ aspects and
perspectives related to the factors that they quoted during the interview. The results
obtained were analyzed using multivariate methods known as the Cluster Analysis
and some descriptive statistical summaries.
2.2.2 The Cluster analysis
The cluster analysis aims to group objects in similar clusters. This analysis
identifies cluster of objects with a strong internal homogeneity and, simultaneously, a
strong heterogeneity among the different clusters. Unlike other multivariate methods,
the cluster analysis does not estimate a statistical variable. Actually, the purpose of
this analysis is to compare different objects based on a statistical variable (the rank
system granted by the interviewees).
33
2.2.3 Dataset
We listed 24 aspects in the questionnaire presumed as possible reasons for
TIMO investments in Brazil. They were divided into macroeconomic, institutional and
forest factors (Table 2.1) in the survey. The interviewees were asked to grand each
aspect from 1 to 5, in which the number 1 was assigned to an unimportant or none
influence in the investors decision and 5 to the most important aspect in the
investment strategies.
34
Table 2.1 - Variables used for the ranking questions
Variables Broad Factor
Investment returns Forest
Investment risks Forest
Timber markets Forest
Environmental laws Forest
Technical capacity Forest
Forest certification Forest
Social/community relation Forest
Timber growth rates Forest
Incentives and subsidies Forest
Land ownership laws Institutional
Tax complexity Institutional
Ease of doing business Institutional
Land price Institutional
Tax rates Institutional
Infrastructure Institutional
Current land use Institutional
Land location Institutional
Access to domestic credit Institutional
Political risk Macroeconomics
Market size Macroeconomics
Trade Macroeconomics
GDP Macroeconomics
Personal risk Macroeconomics
GDP Growth Macroeconomics
35
2.2.4 The Cluster Method
2.2.4.1 Software R
We used the R statistical software, version 2.1.4.1 for the cluster analysis. The
distance analysis was performed by using the ecodist package of the software. All
the commands used are shown in Appendix 4.4.
2.2.4.2 The Cluster analysis
We used the hierarchical method in the cluster analysis. This method is based
on hierarchies of likelihood (or unlikelihood) scores, which the results are expressed
as dendrograms and the distances along one axis represent degrees of likelihood (or
unlikelihood). This method relies on three characteristics: (1) simplicity, (2) adequacy
to the variables selected and (3) mostly, no need to determine parameters (called
“seeds”) before the analysis as in non-hierarchical methods (HAIR, et al., 2007).
After selecting the hierarchical method, the similarity index was computed. The
correlation coefficient was the most adequate indexes for the present dataset; other
indexes, such as Mahalanobis and Euclidean Distance showed less stability.
Therefore, we measured the correlation between the variable resulting in a
correlation matrix. The correlation is defined by the following formula:
∑ ( ) ( )
√∑ ( ) √∑ ( )
( )
√ ( ) ( ) (2.1)
Where:
and are the values measured,
and are the means,
Cov means the covariance and,
Var means the variance.
The variables were identified and grouped forming different clusters using the
correlation measure.
36
2.2.6 Hierarchical Algorithms
The cluster procedure was performed using Complete linkage algorithm. This
method is based on the maximum distance between observations in each cluster. At
each stage of the hierarchical procedure, clusters with the shortest maximum
distance (most similar) are combined.
In others words, the distance between clusters is computed as the maximum
distance between a pair of objects; one in one cluster, and one in the other (HAIR, et
al.,2007) (Graph 2.1).
Graph 2.1 Example of Complete – linkage method
37
The Complete-linkage criterion is expressed mathematically as:
( ) ( ( )) (2.2)
Where:
D(X,Y) is the distance between clusters,
d(x,y) is the distance between objects and,
x and y to X and Y.
2.2 Results
In this section, we present the results of the survey and analyses. A general
overview of the survey respondents is shown first. Then, aggregated results and
results by factor are discussed. Finally, we show the results of the cluster analysis.
2.3.1 Participants
We conducted the interviews in person and by conference calls between April
17 and June 18, 2012. Among the TIMOs with current investments or interested in
investing in Brazil, eight participated in the structured interviews.
The number of participants was considered reasonable due to the current
numbers of TIMOs effectively investing in Brazil. According to research conducted by
CONSUFOR, in 2009, six TIMOs are investing in Brazil (CONSUFOR apud AMATA,
2009). Mendell et al (2011) considered thirteen participants in their analysis of
investors’ perspectives of timberland investments in Colombia.
2.3.2 Background Information
The TIMOs have 15 years of experience on average. The oldest has 40 years
and the youngest has less than 3 years. The number of years in existence, though,
does not reflect managers’ experience in managing forest assets. Almost all
interviewed experts worked either for another TIMO or in the forest products industry
before starting their current business. “The market demanded new TIMOs, we saw
an opportunity to found your own”, noted one of the experts about the creation of new
38
TIMOs in the last decades. Staffs of experts that either used to work for others
TIMOs or had experience on other forest companies compose the TIMOs . TIMOs
have been operating in the U.S.A. since 1983, while American TIMOs started their
business in Brazil in 2000.
The location of the TIMOs investments varies according to the business
opportunities and background. According to the respondents, “knowing the location
facilitates the market and risk analysis”. Currently TIMOs are investing in Uruguay,
Eastern Europe, Brazil, China, New Zealand, Australia, the U.S.A. and Canada. Most
participants interviewed had assets in the Northeastern and Southeastern regions in
the U.S.A. In Brazil, most of the forest assets are located in the Southern region.
TIMOs do not demonstrate any specific strategy or preference for specific
species. Normally, the selection of species is based on the market demand.
However, some TIMOs are specialized in a class of species such as hardwood and
pine. “The specialization makes us and our clients more comfortable to invest in
some regions”, noted one of the respondents.
Most of TIMOs interviewed (42%) are Limited Liability Corporations. C-
Corporation and S-Corporation account for 28% and 14% of the TIMOs in the USA,
respectively. This diversity of business type does not exist in Brazil, where 100% of
the TIMOs are registered as Limited Liability (Limitada) companies.
Even though for legal and commercial purposes they were registered under the
same business category in Brazil, TIMOs adopted different strategies to start their
business. The most used strategies involved acquiring an existing company,
developing a partnership with a local company and establishing their own branch.
The participants stated that the legal arrangements in Brazil are a very bureaucratic
process; “It is by far the most arduous process among our forest assets” said one of
the interviewees. This obstacle to do business is corroborated in other studies. Brazil
is among the most difficult countries to do business in the world (THE WORLD
BANK, in 2012). The country is the 126th place of 183 countries ranked by the
financial institution. Among the Latin America and the Caribbean countries, Brazil
takes the 28th position of 32 countries. Chile is in the first position among the
countries of Latin America and the Caribbean and by far the most promising in this
aspect occupying the 35th position in the world.
39
2.3.3 General Analysis
For the ranking of the broad factors that affect investments, the forest features
were more relevant in the investment decision (Table 2.2). However, this result
should be seen with caution because the standard deviation was greater for this
aspect. The macroeconomic factors followed by the institutional factors showed a
lower standard deviation. Therefore, the TIMOs tended to have common opinions
about these two aspects.
Table 2.2 Investment decision factors
Macroeconomic Institutional Forest
Average 3.64 3.54 3.89
Standard Deviation 0.64 0.84 0.96
For individual investment decision factors, investment returns and risks were the
most important aspects in an investment decision (Table 2.3).
40
Table 2.3 Rank of the investment factors
Aspect Sector Grade Rank
Investment returns Forest 5.00 1
Investment risks Forest 4.71 2
Political risk Macroeconomics 4.50 3
Timber markets Forest 4.43 4
Land ownership laws Institutional 4.43 4
Market size Macroeconomics 4.33 5
Environmental laws Forest 4.29 6
Tax complexity Institutional 4.00 7
Technical capacity Forest 3.86 8
Forest certification Forest 3.86 8
Ease of doing business Institutional 3.86 8
Social/community relation Forest 3.71 9
Land price Institutional 3.71 9
Tax rates Institutional 3.71 9
Trade Macroeconomics 3.67 10
Infrastructure Institutional 3.57 11
Current land use Institutional 3.57 11
Land location Institutional 3.57 11
Timber growth rates Forest 3.43 12
GDP Macroeconomics 3.17 13
Personal risk Macroeconomics 3.17 13
GDP – Growth Macroeconomics 3.00 14
Incentives and subsidies Forest 1.71 15
Access to domestic credit Institutional 1.43 16
The top 5 elements are composed by 50 % of Forest, 33% of macroeconomic
and 17% of institutional factors, while, the last 5 elements are composed by 22 % of
Forest, 33% of macroeconomic and 44% institutional. These individual elements are
discussed later in this section.
The views differed in terms of the importance of the criteria studied. One
participant had similar opinions as the average results, which showed that
41
macroeconomics and forest had 40% each and institutional 20% of importance in
decision for timberland investment. Another participant claimed that the institutional is
the most important factor. He states that a weakness in institutional factors could
make the investment unviable in the first analysis. “There must have an institutional
support from the government to make all kinds of investment viable”, concluded one
of the participants.
Other TIMOs preferred to discuss specific factors, such as return, risk
diversification, land price and the timber market. “The factors complement each
other; however, some clients would like to see a few numbers, mainly the investment
returns” observed one of the participant. In general, they agree that, all factors are
relevant and some of them demand more attention than others, depending on the
objective and strategies adopted by each TIMO.
2.3.4 Broad Factor Analysis
Our respondents indicated that, the decision for an investment is based on a
balanced and meticulous analysis of a broad range of macroeconomic, institutional
and forest factors. Nevertheless, when participants were asked about how they
decide on a new timberland investment, the influence of macroeconomic factors such
as, cash flow analysis, political stability, timber markets, and land liquidity were
mostly cited.
American TIMOs are still looking for opportunities in the U.S.A.; however, land
scarcity, higher prices and the current international experience led them to invest
overseas. They claim that the current moment is favorable for international
investments. The tradeoff between risk and return is adequate with their expectation.
Furthermore, the access to different market minimizes the risk by diversifying their
portfolio (FU, 2012; BLOCK; SAMPLE, 2001; MILLS; HOOVER, 1982; REDMOND;
CUBBAGE, F. W., 1988b)
The process of investing internationally is driven by two initiatives: organization
seek buyers willing to invest in forest assets. Most TIMOs are currently conducting
diligent analysis of investments overseas and demonstrating their potential returns
and risk to their clients. On the other hand, some TIMOs analysis initiative comes
from the client as cited by one of the respondents: “We invest wherever the clients
say so”; “We manage land according to the client’s choice”.
42
Investments in tree plantations are the most popular among the TIMOs. The
property location is the decisive reason in the process of choosing between
plantation and natural forest management. In the U.S.A., investments in the Southern
region are mainly in forest plantation due to the local market conditions and favorable
forest characteristics. Investments in natural forests are made in a few regions in the
U.S.A. and in Europe. TIMOs state that the legal and political risks are too high
compared to the return of investments in tropical forests.
2.2.5 Investment decision
As mentioned before, the decision on a timberland investment is a careful
process. Each TIMO has its own strategy and investment preferences. This reflects
directly on the way they analyze the assets returns and risks. The following topics
discuss the impact and the different perspectives of macroeconomic, institutional and
forest factors on TIMOs’ decisions.
2.3.5.1 Macroeconomics
Political risk and market size are the most important factors in the
macroeconomic analysis (Graph 2.2). According to TIMOs, investors considered the
political situation crucial in an investment analysis. Moreover, political issues are
largely reported in different means of communication such as television and the
Internet. One of the respondents mentioned as example the nationalization of a
Spanish oil company (Repsol) in Argentina recently: “Nowadays, Argentina is not an
interesting place to invest and it will take a long time to become interesting again”.
43
Graph 2.2 Rank of the macroeconomic factors of timberland investment
Large markets guarantee large wood consumption level and thus, a safe market
in the long term. Personal risk and GDP growth rates were considered less important
compared to other macroeconomic factors. Most participants considered the GDP
more important than the GDP growth. “GDP is a better indicator of the actual
consuming power”, noted one respondent .Most TIMOs’ assets are in countries with
high GDP levels and with growth rates either stable or constantly increasing, e.g., the
U.S.A., Brazil and China. However, when considering the potential demand for
wood products, the countries with high growth rates become markets that are more
attractive in a short-term.
Personal risks are taken into account, but not as much as other factors in the
investment decision. However, few participants considered this aspect essential as
we can observe in the standard deviation of 1.51 (Graph 2.2). “We will not invest in a
country where our employees might be exposed to some danger”, said one of the
respondents.
Besides the macroeconomic aspects already incorporated to the questionnaire,
TIMOs reported other four important aspects: (i) corruption, (ii) land availability, (iii)
currency exchange and (iv) legal risk.
Corruption levels are based on the Corruption Perception Index (CPI),(TI, 2010)
elaborated by the non-governmental organization called Transparency International,
since 1995. CPI ranks corruption levels from 1 (high level) to 10 (lower level). As
corruption is correlated with other investments risks, higher levels discourage
investments in certain regions, e.g., most African continent and Middle Eastern
countries have CPI below 2, while the U.S.A., Brazil and China have 7.1, 3.8 and 3.6
44
respectively. “However, if it does not harm the business, some level of corruption is
acceptable”, noted one of the respondents.
Land availability was an interesting aspect cited during the interviews. “Some
places have everything we require to invest, but finding available land demands
patience and hard work”, explained one of the interviewees. In other words, some
regions are very attractive, but do not have land available with desirable
characteristics, even if the TIMOs are willing to pay higher prices. In a competitive
land market, most large and attractive timberlands are scarce or inexistent. Among
other reasons, land availability is driving TIMOs to new unexplored forest regions.
Exchange rates were mentioned as an important aspect regarding the
international investments. The acquisition power of American TIMOs is higher when
the dollar is stronger than the local currency as one of the respondents quoted: “In
the end, we have to convert everything to dollars; so, the current exchange rate can
make a huge difference”. In Brazil, for example, the exchange rate between dollar
and real affects land acquisition regarding competitiveness of timber products for
exports .Therefore, the entire timber production chain is affected by the exchange
rate level.
Concerns with the legal risk are correlated with political risks, according to
interviewees. TIMO feels more comfortable to invest in a country where the legal
system demonstrates stability. The changing on the Código Florestal in Brazil is good
example of legal risk as a TIMO stated: “We would like to be certain we are working
legally. This uncertainty is not good for the business”. As the assets are appraised
annually, the change in the land use laws would compromise the value as well as
future acquisition decisions.
The lack of a land title was another concern mentioned by the TIMOs. In the
acquisition process, all of the TIMOs complained about the difficulty to find a trusted
land title. As they reported, this process should be the easiest part in the negotiation;
however, it is a critical decision. In Brazil, according to the Brazilian Colonization and
Land Reform (INCRA), 70% of the territory or 605 million hectares (1.5 billion acres)
were registered legally in 2012. It does not mean that these properties are regulated
according to the environmental laws. The absence of a land title or the presence of
the illegal ones can be found more frequently in regions with less social and
economic development. Even Brazilian investors hire specialists to verify the
legitimacy of the title, thereby increasing the cost and time of negotiation. “The high
45
risk to buy an illegal or nonexistent property has delayed or cancelled some TIMOs’
acquisitions”, concluded one respondent.
2.3.5.2 Institutional
According to the rank elaborated with the institutional aspects, landownership
laws and tax complexity are the most important factors for timberland investment
(Graph 2.3).
Graph 2.3 Rank of the institutional factors for timberland investment
Land ownership laws affect the acquisition process. Most TIMOs are concerned
with restrictions in Latin America for foreign landownership; Brazil and Uruguay were
the most quoted examples. Both countries claim national security and sovereignty to
justify such restrictions. TIMOs understand that this law should be reconsidered for
large territories such as Brazil. However, they still feel motivated to invest in the
country even with this obstacle; “It made the acquisition harder, but not impossible”
affirmed one of the interviewees. On the other hand, it drives investors to search for
other regions. “These restrictions are affecting the decision whether or not to invest in
the country for some clients”, as noted by one of the TIMOs. The Brazilian
Association of the Planted Forest Producers (ABRAF) claims that, since the adoption
of land purchase restriction to foreign investors in 2010, many projects in the forest
sector were cancelled or suspended involving a total value of US$ 20 billion dollars
(ABRAF, 2011).
46
Tax complexity was mentioned due to its influence on the cash flow analysis. In
a complex system, it is necessary to hire an experienced accountant in order to
decide the best tax strategy. This factor was more relevant in timberland investments
overseas as noted by one of the survey participants “We understand the tax system
here, the problem is the tax complexity overseas.”
Business viability affects investments according to the country. It was
considered an important factor in general, TIMOs showed more patience with new
markets. The slow acquisition process is attributed to the need for diligence studies.
After the studies are concluded, the bureaucratic process does not take longer than
required. In Brazil, investors expected a maximum period of 6 months after the due
diligence analyses. This time is six-fold longer than in the USA, where all the
transaction can be done in a few days (THE WORLD BANK, 2012).
However, the attractiveness of Brazil to the forest business seems to overcome
difficulties to start a business, as noted by one of the participants: “Brazil is among
the countries where we have to be most patient.” Surprisingly, land price was ranked
in the 4th place among the institutional factors. The high land price could compromise
the investment; on the other hand, for some TIMOs land price is less relevant for
long-term investments. They argue that land price is more important after the
acquisition, during the asset management. The land price is compensated by the real
estate market: “If we can make money selling the property, we will purchase it”, “our
business is the timber as well as the land market”, noted by one of the interviewees.
The standard deviation of the land price aspect was the highest in the ranking.
This result demonstrates the significant caution of some TIMOs regarding this aspect
while others do not consider it essential. “We look for investments worldwide, if we
see the land price as a barrier in a determined country, we will look for other
opportunities elsewhere”, concluded one participant.
Land location was pertinent for all TIMOs except one; “the market will show
where the good land is”. This factor might not have influence in a country with access
to good transportation systems, infrastructure and a mature market, such as the
U.S.A. On the other hand, in developing countries with a poor infrastructure system,
the choice of a property near or with easy access to the road means the tradeoff
between success and failure. The difficulty to transport the wood would be so high
that, it would demand investment in infrastructure beyond the property limits. “There
would be a high cost effect on timberland located in regions with precarious
47
infrastructure”, noted one of the TIMOs. On the other hand, the vertically integrated
companies in Brazil invest in infrastructure like roads and even in harbors to transport
their products. TIMOs do not seem to make such external investment. According to
them, the production chain is one of reasons that places infrastructure as important
as the land location for timberland investment.
Access to local credit was considered little or irrelevant by the respondents for
investments in timberland, as can be observed in the following quote: “A timberland
investment cannot be based on local credit; the investment must be profitable by
itself.”
2.3.5.3 Forest
As expected, investment returns and risks are the most important among the
forest aspects (Graph 2.4). “Risk and investment returns are the reason for every
investment”, “Ultimately, these two aspects decide the present and future
investments” and “These variables included all the other aspects for the investment”
are some examples of the definition of investment returns and risks by the
participants. Additionally, investment returns were considered even more important
than the risks. According to TIMOs, return of investments is easier to figure out with
numbers, while, some risks are impossible to predict.
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Graph 2.4 Forest factors on timberland investments
The timber growth rates were not very relevant in the investment analysis
reported by the TIMOs; the investment is closely correlated with the market. In other
words, the price paid by the market converts the timber growth rate automatically to
monetary value, subsequently, integrated to a cash flow models. “The timber price
must correspond with the timber growth”, affirmed one of the interviewees. Another
TIMO noted that, “In some markets, the timber will not pay a premium price for slower
growth or higher quality wood, therefore, fast growth is important and financially
advantageous”.
TIMOs are open to the process of timberland certification, according to one of
the respondents. Fifteen per cent of the TIMOs interviewed prioritize forest
certification. However, according to them, this process will be done if the market or
the clients demand such regulation. “The timber certification is driven according to
the timber market demand, if there is a payback of the process, we will certify our
forest”, quoted one of the TIMOs. Some specific export markets and European
clients have the highest concern with forest certification.
The technical capacity is an essential factor discussed during the interviews.
The communication between the TIMOs and the company that manage the forest is
the main aspect in international investments. As reported by a TIMO: “In Brazil for
example, forest management is heavily based on volume increment models. The
economic aspect is much more relevant to us”.
49
Incentives and subsidies were not as important as the other factors studied in
timberland investment. The reason is the same as the access to local credit “the
business cannot rely on these bonuses”, as reported the TIMOs.
2.2.6 Cluster Analysis
The cluster analyses we performed are described below. We used the cluster
approach to identify factors that are related to each other in making an investment as
a new means to test the merits of the IADB approach we used initially.
2.2.6.1 Variables Analysis:
The cluster analysis was used to assess the broad factors that affect TIMO
forest investments by analyzing the pattern of each individual factor discussed
above, without any prior classification into broad factors. The analysis showed that
the variables are not allocated to the same broad factors (microeconomics,
institutional and forest) as presented at the beginning of this research. Instead, the
following cluster analysis dendrograms demonstrate the division of the individual
variables in two broad clusters:
50
Graph 2.5 Cluster Dendrograms
Where:
51
Table 2.4 Cluster dendrograms results
Code Variables Broad Factor Cluster
X23 Forest certification Forest
A
X16 Timber growth rates Forest
X17 Timber markets Forest
X21 Environmental laws Forest
X7 Infrastructure Institutional
X9 Land ownership laws Institutional
X10 Current land use Institutional
X12 Land location Institutional
X14 Tax rates Institutional
X15 Tax complexity Institutional
X18 Investment returns Forest
B
X19 Investment risks Forest
X22 Social/community relation Forest
X20 Technical capacity Forest
X24 Incentives and subsidies Forest
X8 Ease of doing business Institutional
X13 Access to domestic credit Institutional
X11 Land price Institutional
X1 GDP Macroeconomics
X3 Market size Macroeconomics
X2 GDP Growth Macroeconomics
X6 Trade Macroeconomics
X4 Political risk Macroeconomics
X5 Personal risk Macroeconomics
The variables in cluster A and cluster B were slightly different from the broad
factors suggested at the start of the research. Cluster B has variables that are
directly connected with economic factors, except for technical capacity and
social/community relation. Cluster A is composed mostly by forest and institutional
52
variables that indirectly affect timber investment. The timber market is the only one
directly related with economic issues.
Some of the individual relationships in the dendrograms seem quite logical,
which help to support the merits in the cluster analysis. For example, in class A,
factors X14 and X15, tax rates and tax complexity were in the same branch (Graph
2.5). Forest certification and current land use were “twinned” in one branch, as well
as land ownership laws and infrastructure. Timber growth rates and land location
were grouped together at a higher level in the dendrograms. These were all
combined to determine most forest and institutional factors in Cluster A.
In Cluster B, the four sets of twins at the lower levels: (1) GDP and market
size, (2) investment returns and investment risks; (3) social/community relations and
technical capacity; and (4) incentives and subsidies and political risk. All in all, these
pairs were moderately to extremely logical; risks and returns of investment for
example had the highest grade in the general analysis (Table 2.3) and their relation
and importance were also mentioned in open questions (topic 2.3.5.3 Forest).
Another result that also supported the cluster approach was the division of the
institutional and forest factors that were divided between factors that have high
correlation to the market (X19, X18, X22, X20, and X24 of the forest group and X8,
X13, X11 of the institutional group) and high correlation with no parameters for the
market (Cluster A).
The results showed therefore, the allocation of these variables in two factors
such as institutional and biological factors for cluster A and economic factors for
cluster B. Other detailed breakdowns many be conceptually useful; however, the
interviews indicated that TIMOs operationalized them somewhat differently in their
decisions.
2.2.7 Minimum Acceptable Rate of Return
The investment decision analysis does not differ for countries as noted by 50%
of the respondents. One of the TIMOs claimed that only an adjustment between risk
and return of investment is required. However, respondents say that more caution on
the decision is necessary for investments overseas: “Some factors in Brazil are not
as clear as they are in the U.S.A”.
53
These aspects directly affect the financial criteria such as Minimum Acceptable
Rate of Return (MARR), also called discount rate. The discount rate that TIMOs use
in Brazilian projects is 5 % higher on average than in the projects in the U.S.A. (Table
2.5).
Table 2.5 Discount Rate
Country Max Min Average
Brazil 16 8 11.35
USA 11 5.5 6.11
The value of the discount rate reflects directly the risk of the investment,
according to one TIMO. This risk can vary according to the country and the region in
the same country. “In remote regions in Brazil the discount rate used are higher than
in traditional timberland regions”, reported one of the interviewees. In some cases,
the risk in Brazil is even lower than in USA, specifically in the Southern region, due to
the strong domestic market and the current economic situation.
The discount rates found in this research showed different results compared to
the current literature. In Brazilian investments, LIMA et al., 1997, found the range of
4.5 % to 10.5 % in the linear model analysis. BERGER et al., 2011 used 6 % as a
discount rate in an economic analysis of pine plantations in Parana State, Brazil.
The Internal Rate of Return (IRR) demonstrated higher value than the discount
rates used by the TIMOs. CUBBAGE, F. et al., 2010 implemented cash flow analysis
in timberland investments in Brazil and obtained a range between 16.3 % with Pinus
Eliotti and 25.5 % with E. grandis to sawtimber production without including land cost.
With land cost included, this figure decreased to 6 to 8 %. BERGER et al., 2011 has
a range between 11.8 % including the land acquisition and 22.1 % without including
the land acquisition. In comparison, for timber investments in the U.S.A., CUBBAGE,
F. et al., 2010 found the range between 8.5 % in pine investments in the Southern
region of the country and 6.5 % in Douglar-Fir, without including land cost.
54
2.2.8 Investors’ Perceptions
Only a few respondents made comments about their investors’ perspectives and
objectives. The TIMOs that participated in interviews have pension funds, insurance
companies, financial institution and universities as clients. Pension funds are the
major clients, mentioned by approximately 83 % of all respondents.
Among the main reasons to choose timberland as an investment, portfolio
diversification was the most often cited. Investors search for an asset that has the
minimal correlation with their portfolio. Thus, any decrease in one asset does not
affect other investments. Other characteristics for forest investments mentioned by
the interviewees were the merits as inflation hedge and capital preservation.
Most investors expect different returns from forest investments in different
countries. They expect more returns from investments in countries with higher risk. “It
is correlated with the risk”, explained one of the respondents. Therefore, they
demand more information for new investments. According to the TIMOs, the main
information demanded by investors regards political, liquidity, and physical risks on
the forest assets. Certification was cited as one of the requirements from European
investors. Social and other types of sustainability indexes are not required by
investors.
Investors who want to purchase any forest asset normally contact TIMOs by
networking, presentations and/or events. The minimal capital required ranges from
US$1 to US$5 million for separate accounts and US$5 to US$10 million for pooled
common funds. In practice most investors/investments are much larger, probably
US$50 to US$100 million. Also, most TIMOS are often willing to make individual
forest investments of US$25 million or more per transaction.
2.3 Future Perspectives
Similarly to the preceding topic, not many respondents opined about future
opportunities. There were positive expectations regarding future investments and
challenges in the timberland market among the TIMOs. All of the interviewees were
very confident and looking for new business opportunities to invest worldwide.
Asia, Latin America and the United States are among the countries that they are
always looking for an opportunity. They say Brazil is one of the most attractive
55
countries in the present and future acquisitions. TIMOs that still do not have business
in Brazil plan to make acquisitions shortly. Additionally, TIMOs that already have
business in the country plan to expand their investments.
The business environment in Brazil could be even more attractive if some
obstacles were removed or minimized. The main hindrances refer to the lack of
information on Codigo Florestal, the complex tax system and the environmental
pressure for the plantation of fast-growth species. The recent prohibition for foreign
landowners to hold most investments of a company also has been an obstacle for
TIMOs since 2011.
2.4 Discussion
The results confirmed that TIMOs have different strategies for the management
of current assets and future acquisitions. As any portfolio investment manager,
TIMOs follow the basic concepts of Modern Portfolio Theory: the maximization of
expected returns and minimization of investment risks (FU, 2012;CARROLL, 2003;
REDMOND; CUBBAGE, F. W., 1988b). The more managers diversify their
timberland portfolio, the lower the risks and the more balanced expected returns they
will have (CAULFIELD, 1998; REDMOND).
Features of forest assets encouraged institutional investors to include them in
their portfolio. The impact on the market can be seen by the intense landownership
change in the U.S. over the last 30 years (HAGENSTEIN, 1984; ZHANG et al.,
2012). and the globalization of the TIMOs investments. Little investment has
occurred in other traditional countries with an attractive forest sector, e.g., Sweden
(LÖNNSTEDT; SEDJO, 2012), while South America is becoming more promising as
shown in our research and in Mendes (2005).
The respondents of the survey affirmed that investments in forest assets have
opportunities throughout the world. When invested in the right place and time, forest
assets can provide opportunities that are more profitable and reduce the risk in
portfolios. In general, TIMOs expect better returns from international investments due
to the higher risk and the economic analysis computed this expectation; minimum
Acceptable Rate of Return are higher in Brazil than in the U.S.A. as measured in
Table 2.4 in topic 2.2.7 (Minimum Acceptable Rate of Return). Although their
56
individual decisions are driven by TIMOs’ expertise and risk aversion levels, all
TIMOs share many aspects.
Previous researches on investments in Latin America shows that investors’ are
concern with the macroeconomic, institutional and forest aspects (CUBBAGE et al.
2010,MENDELL, B. C. et al., 2011). Mendell. et al. (2011) interviewed several
institutional investors about investment strategies in Colombia. The respondents
demonstrated similar concerns about risk and return. Political stability, timber market
and landownership are the most quoted concerns. According to Mendel et al (2011),
international investments involve a significant risk, most countries do not guarantee
basic legal structural issues and can have capital repatriation issues.
Most factors studied in this research have a significant impact on the investment
strategies. As every economic analysis, risks and returns were ranked as the most
important aspects .However, these two factors alone are not enough to convince an
investor to invest overseas. It is required broad knowledge about economics,
technical and political aspects to provide accurate results.
There are different strategies and features that can influence investors’
decisions for an investment. As observed in the cluster analysis, there are two main
groups of variables that have similar behavior in forest asset investment, according to
the TIMOs. These groups can be denominated as (i) Institutional and Forest factors,
and (ii) Economics factors.
On the other hand, the Forest Investment Attractiveness Index (IAIF) developed
by the Inter-American Development Bank (IADB) uses a different segregation in their
investment analysis. The IAIF uses three groups of Sub-Index defined as: (i) SUPRA:
macroeconomic factors and to other factors that can affect the profitability of any
productive sector on the country, (ii) INTER: factors that could affect the forest-
industrial business and, (iii) INFRA: factors related to the forest sector that could
affect profitability of forest-industrial business (IADB, 2008)
The groups formatted in the cluster analysis indicate different strategies adopted
by the different players in the forest sector. The study conducted by IADB aimed to
formulate an index for the entire forest sector, including the industry and independent
timber producers. This can justify the division in three groups; however, when
focusing on specific players in the forest sector, investors seem to aggregate key
variables into two groups, as shown in our research.
57
Another aspect we observed was the link between investors’ strategies and
TIMOs’ business plan. Clearly, the business plan elaborated by TIMOs is adapted to
each client’s feature. Forest certification requirement, for example, is often required
by European funds; therefore, TIMOs’ business plans present this option to
European clients and its pros and cons. The different requirements in a business
plan are discussed by Manson & Stark (2004). According to the authors, each
investor has different criteria to approve an investment according to the business
plan presented. They affirm that bankers focus heavily on the financial criteria while,
venture capitalists and business angels balance the investment analysis between
market and financial criteria. Comparing these results to ours, TIMOs’ investors seem
to have similar preferences to venture capitalists and business angels. TIMOs
considered the financial criterion essential (table 2.3, topic 2.3.3 General Analysis).
On the other hand, given that forest management is a long-term investment, the
market must be strong and stable enough to guarantee low risks during the period of
investments.
2.5 Conclusion
The recent internationalization of forest investments has driven TIMOs in the
United States to different markets and prompted greater interest in making
investments abroad. TIMOs want to make investments in Brazil and elsewhere, and
they require deeper information about those opportunities and the use of economic
analysis for their decisions.
Understanding the TIMOs’ strategies gives support to countries and investors to
make better decision in timberland investments. Governments that want to attract
new investments must show a safe environment for business as well as attractive
silvicultural and economic performance. An improved connection among TIMOs,
countries and investors can increase opportunities. While governments can develop
their socio-economic situation by enhancing the timber production chain, TIMOs and
investors can enrich their portfolio with assets that are more profitable.
The traditional forest producing countries, namely the U.S.A., Brazil, Chile, and
China still have land available for new investments. However, other governments
have become more aggressive and offered more incentive to foreign investors in
timberland, e.g., Colombia (Mendell et al, 2011). This market competition is good for
58
investors and for the entire timberland market. Nevertheless, TIMOs are just a part of
the timberland market; further studies must be conducted to better understand the
strategies of the other investors.
The models adopted by the U.S.A., where TIMOs and REITs own the land, tend
to be used in other countries. This perspective motivates even more the participation
of the institutional investors. In addition, new agricultural and forest production
frontiers must be explored in Latin America, Asia, and Africa.
59
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de caso do setor florestal. 2007. Thesis ( Master in Forest Science) – Universidade
Federal do Paraná, Curitiba, 2007. Available at <http://www.floresta.ufpr.br/pos-
graduacao/defesas/pdf_ms/2007/d484_0675-M.pdf >. Accessed in: 3 mar. 2013.
ZHANG, D.; BUTLER, B.; NAGUBADI, R. Institutional Timberland Ownership in the
US South: Magnitude, Location, Dynamics and Management. Journal of Forestry,
Washington, v. 4, n. 11, p. 355-361, 2012.
64
3 THE ECONOMIC COMPETITIVENESS AMONG TRADITIONAL REGIONS AND
NEW AGRICULTURAL FRONTIERS IN FOREST INVESTMENTS IN BRAZIL.
Abstract
Forest economists from financial institutions and government constantly analyze
the economic aspects of investments in forest assets to support their decision-
making process. They are seeking for new opportunities and the timberland market
trend. In Brazil, forest business is expanding into areas where silviculture is not a
conventional activity. This chapter investigates the aspects related to forest project
analysis in the states of São Paulo, Mato Grosso do Sul and MAPITO (an acronym
for the neighboring states of Maranhão, Piauí and Tocantins). To determine the
economic feasibility we performed Net Present Value (NPV), Land Expectation Value
(LEV), Internal Rate of Return (IRR) and Willingness to Pay for Land, considering
future land value (WPL). Moreover, the criteria outputs were simulated by Monte
Carlo methods and sensitive analysis. The attractiveness of the regions varied
according to financial criteria used by investors. The WPL analysis showed the best
returns among the criteria analyzed; when considering an increase in the land value
presented, the WPL presented a return of R$ 871.79, R$ 1,427.49 and R$ 1,138.69
per hectare in the states of MAPITO, Mato Grosso do Sul and São Paulo,
respectively. MAPITO was the region where the current land price had less effect
than timber market and operational efficiency. On the other hand, the State of São
Paulo is not as attractive in reason of the high land prices.
Keywords: Forest valuation; Investment analysis; Return rate; Monte Carlo
simulation; Risk
65
Resumo
Economistas Florestais de instituições financeiras e governamentais analisam
constantemente os aspectos econômicos dos investimentos em ativos florestais.
Investidores em florestas plantadas procuram novas oportunidades para maximizar
seus retornos. Brasil é um país em que está passando pelo processo de expansão
de suas áreas de florestas plantadas para regiões com pouca tradição em
silvicultura. Esse capítulo tem como objetivo estudar a viabilidade econômica de
projetos florestais nos estados de São Paulo, Mato Grosso do Sul e MAPITO (
Maranhão, Piauí e Tocantins). Foram utlizados como critérios econômicos o Valor
Presente Líquido (VPL), Valor Experado da Terra (VET), Taxa Interna de Retorno
(TIR) e a Valor Pago pela Terra (VPT). Posteriormente, esses critérios foram
simulados pelo método de Monte Carlo e análises de sensibilidade.A atratividade
das regiões variam de acordo com o tipo de critério econômico utilizado. As análises
do VPT apresentaram os melhores retornos, quando considerando o aumento no
valor da terras teve um retorno médio de R$ 871.79, 1,427.49 e 1,138.69 por
hectares nos estados do MAPITO, Mato Grosso do Sul e São Paulo
respectivamente. Os projetos florestais na região do MAPITO sofreram menor
influência da variação de preços da terra que a variação de preços da madeira, da
produtividade florestal e dos rendimentos operacionais. No estado de São Paulo, por
outro lado, o preço de terra teve maior impacto no resultado final do fluxo de caixa
que os outros fatores analisados.
Palavras - chaves: Avaliação Florestal; Taxa de retorno; Simulação de Monte Carlo;
Análises de investimentos; Risco
66
3.1 Introduction
Similar to the first settlers during Brazil’s colonization, the Brazilian agribusiness
sector has been searching for new opportunities and resources in unexplored areas
over the last decades. Competition in traditional forest-planted areas has increased
land prices and consequently, initial investment in land acquisition became higher
than years ago. Furthermore, all speculation around the new agricultural frontiers has
attracted companies, independent producers and institutional investors to invest in
agriculture and tree plantations in these regions
This chapter investigates the economic competiveness between the traditional
timber-regions and the agricultural frontier in forest assets investments in Brazil. We
will discuss the main aspects that affect the decision-making process to invest in a
given region. Additionally, we performed a cash flow analysis to examine the
economic criteria results and their sensibility in returns of investments of forest
projects.
3.1.1 The forest sector in traditional regions in Brazil
Brazil is a worldwide reference in silviculture of fast growth trees due to the
favorable soil and climate conditions, investments in new technologies and genetic
improvements. Productivity levels are the highest in the world in Brazil; the main
species planted (Eucalyptus) can growth annually at range between 20 to 70 m3 ha-1
(GONÇALVES et al., 2013).
Concomitantly to the physiological aspect, the Brazilian government has an
important contribution to success of tree plantations by granting tax incentives to the
forest sector between the 1960s and 1980s (BACHA,2008). The combination of all
these aspects boosted the installation of forest companies in the country and
expanded planted areas.
In 2011, the total area covered by planted trees reached 6.5 million hectares
(ABRAF, 2012); most of it occupied by the genus Pine or Eucalyptus. The Southern
and Southern regions were the pioneers to establish the first commercial forest
plantations. In 2011, the total roundwood production in these regions amounted 98
67
million cubic meters, which accounts for 77% of the total national production (116
million cubic meters) (IBGE,2013). The region has 4.8 million planted hectares (73 %
of the total) and the highest concentration of wood processing mills per planted
hectare. There are 23 companies altogether, where 7 produces wood panels
(Medium Density Fiberboard, Oriented Strand Board), 6 produce cellulose and paper
and 10 steel mills.
There is a large economic flow in the forest industries, once they provide a large
amount of jobs and tax. According to ABRAF2012, the sector generated 1.2 million
direct and indirect jobs and generated taxes at the amount of R$ 7.4 billion in 2011.
The benefits of forest plantations exceed the socio-economic requirements,
most industries in Brazil are subject to a severe social and environmental regulation
in order to acquire or maintain the forest certification, e.g., Forest Stewardship
Council (FSC). In Brazil, 207.3 million (natural and plantations) hectares are
certificated by FSC. Moreover, the forest industry in the South and Southeast
preserves an area equivalent to 1.5 million hectares of natural vegetation
(ABRAF2012). This area is 10 times larger than the largest national park in the South
(the Iguacu Water Falls Park with 169 thousand hectares).
The establishment of the forest sector in the Southern and Southeastern regions
occurred due to the historic development and the high demand for wood in the
region. With a larger number of companies installed, the region became the most
economically developed and attractive to every economic sector in general.
3.1.2 Business Environment
The South and Southeastern regions are the most economic developed regions
in Brazil. In 2010, the Gross Domestic Income (GDI) of these regions amounted 71 %
of the total in the country (IBGE 2012). The presence of several types of industries
and the high-density population make the consuming sector strong and attractive to
all type of investments.
According to the rank of the best regions to invest in Brazil elaborated by the
Economist Intelligence Unit (EIU) and published by the Brazilian magazine Veja
(2012), the Southern and Southeastern states in the traditional regions are the best
ranked and their business environment is classified as the second highest grade.
68
The EIU rank analyzed 8 aspects regarding the business environment: 1)
Political environment, 2) Economic environment, 3) Taxes and regulations, 4)
Foreign investment policy, 5) Human Resources, 6) Infrastructure, 7) Innovation and
8) Sustainability. In all criteria, the South and Southeast regions were better
classified than the others, except for taxes and regulations, where the Southeastern
and Central-western regions obtained the highest classification.
3.1.3 Forest Sector Investment Expansions
Although Southeastern and Southern region have a better business
environment, the agribusiness and the forest sector investments have followed
different paths and started to produce in unexplored and not very friendly business
environments.
There are evidences that the forest sector is not investing as much as usual in
the South and Southeast. Between 2010 and 2011, the planted area in the
Southeastern and Southern regions shrank 2% and 0.16 %, respectively (Graph 3.1).
Graph 3.1 Planted forest expansion, year basis 2005. Source: ABRAF,2012.
Only one new mill was started in the south, as the company called Klabin is
currently studying the installation of a new mill in the north of Paraná State with
capacity to produce 1.5 million tons of cellulose from Eucalyptus and Pines (KLABIN
S.A., 2011).
On the other hand, the expansion in the Central-western region is clearly larger.
In 6 years, the region has more than doubled the planted areas. The city of Três
69
Lagoas, located in Mato Grosso do Sul State in the Central-western region, is known
as the world capital of cellulose. Two cellulose mills (Fibria and Eldolrado) are
installed in the city and together they produce 2.8 million tons of cellulose per year,
equivalent to 25 % of the Brazilian production (BRACELPA, 2013). Both mills were
started recently, Fibria in 2009 and Eldolrado in 2012.
Eldolrado invested 6.2 billion reais and plans to produce 5 million tons of
cellulose per year until 2020 (CAMPO GRANDE NEWS, 2012). Fibria invested
US$1.5 billion to produce 1.3 million tons of cellulose per year. Fibria’s mill was the
first to produce more than 1 million tons of cellulose per year (FIBRIA CELULLOSE
S.A., 2011).To supply these mills, Fibria has 207 thousand hectares planted
including areas owned by the company and partners, while, Eldolrado has 110
thousand hectares planted, including areas owned by partners. Eldolrado is planning
to reach 160 thousand hectares until 2020.
The border between the states of Maranhão, Piauí and Tocantins, called
MAPITO, is another region that is attracting several investors (FERRO, 2012).
According to Stefano (2009), the group Suzano purchased 35 thousand hectares in
south of Maranhão State. Additionally, Suzano announced the installation of two new
cellulose mills, and one will start to produce at the end of 2013 and another in 2016.
The total investment amounts to US$2.3 billion. These mills will produce 3 million
tons of cellulose per year. Furthermore, Suzano is investing in the production of
pellets for European consumers. The companies says that investments will reach
US$8 million in three new mills to be installed in the region where each mill will
produce 1 million tons of pellets per year (SUZANO, 2013).
As the productions from mills are exported to Europe or/and the U.S.A, the
MAPITO location is strategic. Companies are able to transport the final products
faster than companies installed in the South. Another crucial advantage is the land
availability in the Central West and in MAPITO, the lower competition and lower land
prices make forest projects more attractive and land acquisition easier in these
regions than in the traditional ones (MF CONSULTORIA FLORESTAL, 2010).
3.1.4 Land Market in Brazil
Land price is one of the key factors to make forest projects viable. High
investments in land acquisition impact the cash flow analysis in the first years
70
(BERGER; SANTOS, 2011). Therefore, understanding the land market is essential
for investors to make the best decision regarding time and location.
The land asset is attractive to many types of investors due to the possibility to
gain profits in two ways: 1) the land expected future value and, 2) the productive
capacity (ROMEIRO; SAYAD,1982). The expected future value is highly connected
with market speculation and future production. In less-developed areas, future
investments expectation in infrastructure or any other improvements in the region
adds value to the land. Moreover, the land value is directly connected with the
expected price of its products (ZILLI, 2010). According to the author, as prices of
commodities keep increasing, it will push the land prices upward.
The potential Brazilian agriculture moves the land market in the country. The
current macroeconomic scenario, world demand for bioenergy and fiber and land
availability have encouraged national and international investors to purchase land in
Brazil (KRÖGER, 2012; ZILLI, 2010).
Data from AGRAFNP (2010) shows that Brazil had 104 million hectares
available for agriculture production in 2010. Most available areas are located in the
North and Central-west (Graph 3.2). In these regions, the likelihood to purchase land
with desirable characteristics (low prices, reasonable size, near roads, access to
water sources and good soil condition) is higher than in the traditional regions.
Graph 3.2 Available area for agricultural land per region. Source: AGRAFNP,2009
The interest to purchase land assets has increased the rural land prices in the
last years. The prices of cultivable lands increased 153 % in the last 7 years
71
(AGRAFNP,2013). The Central-western region showed the highest increased with
165 %, while the South presented the lowest with 145 % (Graph 3.3).
Graph 3.3 Average land price in Brazil. Source: AGRAFNP, Adapted by the author
The less expensive lands are located in the Northern region. The lack of
infrastructure, environmental restrictions and conflicts in local properties are some of
the reasons of the low demand for land in this region.
Between 2009 and 2010, land prices declined in most regions in Brazil. This fact
is related with restrictions imposed by the Brazilian Union Legal Council (Advogados
da União), changes in the interpretation of law number 5.709 of 1971 and restrictions
for land acquisition by companies with foreign capital (FERRO, 2012). Despite these
restrictions, land prices increased in the following years. Between 2010 and 2012,
land prices raised 32 % in the country, where, the highest rate observed in the
Central West (42 %) and Northeast (35%).
Investors face therefore a dilemma: they either acquire land in frontier regions
with an apparent tendency for higher profitability or keep their investment directed to
traditional regions with a better business environment, stronger timber market, tree
species productivity already developed and clones already developed and
productive.
72
3.1.5 Resource Focus
The business environment is an important factor that investors use to decide to
invest in a given region. Nevertheless, a detailed analysis is required to support their
decision. In forest projects, components of productivity, market, revenues and cost
performances must be carefully analyzed to provide accurate answers to the
investors. Furthermore, analysis of forest projects becomes even more challenging in
a country with a large territorial dimension like Brazil. An economic analysis, such as
discounted cash flow, must be performed and investors must be aware of the
possible returns and risks.
In a cash flow analysis, land acquisition is a crucial process for the viability of
forest projects; the land acquisitions are normally made during the first years and the
discount rate has lower influence in the present value. On the other hand, future
expectation values of the bare land make land acquisition viable in regions where the
land prices are constantly increasing.
Industries, independent producers and institutional investors are seeking new
opportunities in agricultural frontiers in order to obtain greater returns and
consequently assume higher risks. The traditional regions in the South and
Southeast do not seem as attractive as used to be, mainly because of the higher
initial investment. Based on these statements, this chapter aims to answer the
following hypothesis:
1) Forest investment in the Southern and Southeastern regions is not viable due to
the higher land price,
2) Forest investment in new agricultural frontier is riskier than in traditional regions.
73
3.2 Methodology
Due to the vast sources and types of data, we used different approaches to
achieve a common denominator and thereby compare the economic aspects among
the regions studied. In this section, we will introduce the study location and its
characteristics, including a historical description of geographical locations and land
prices. Afterwards, we will demonstrate and detail the financial criteria and process of
building the cash flow analysis as well as the parameters and the criteria used to
describe the sensitive analysis. We finished this topic by describing the statistical
methods used to fit the distribution and to run the Monte Carlo simulation.
3.2.1 Study sites
The São Paulo State are in the traditional planted forest region and was
selected as their representative state, while, Mato Grosso do Sul and MAPITO are
the new frontiers (graph 3.4).
74
Graph 3.4 Study sites
3.2.1.1 São Paulo State
Located in the Southeastern region, the state of São Paulo has three
predominant climates types: tropical, high tropical altitude and tropical humid (IBGE,
2002). The temperature ranges from minus 0º Celsius, in the areas near to mountain
ranges, in the winter to 40 º Celsius in the summer. The rainfall averages 1,490 mm
per year (CARVALHO, 2005) with heavy rains in the summer and a dry season
during the winter. There are different types of vegetation in the state, ranging from
Cerrado, predominant in dry regions, to tropical forest in coast of the state.
The São Paulo State has the strongest economy in Brazil; its GDP is equivalent
to 33.1 % (1.2 trillion reais in 2010) of the total GDP in the country. São Paulo State
economy is based on industrial and agricultural production. The state is Brazil’s
major sugarcane producer and one of the most important states in the Brazilian
forest sector. The forest sector in São Paulo produces 29 thousand cubic meters of
75
roundwood in 2011, equivalent to the 22 % of the total production in the country,
setting the state as the largest producer in the country (IBGE, 2012). Furthermore,
Eucalypt areas in São Paulo State have the highest average productivity in the
country: 45 m3.ha-1 per year (ABRAF, 2012) thereby making the state even more
attractive.
In terms of planted area, the state has 18 % of the total area in Brazil, where 1.2
million hectares are planted with Pine (150 thousand hectares) and Eucalypt (1.05
million hectares) (ABRAF,2012). Additionally, São Paulo has the largest
concentration of the verticalized forest companies in Brazil, with 24 % of the 54
companies located in the state.
3.2.1.2 Mato Grosso do Sul State
The state of Mato Grosso do Sul is located in the Central-western region and
has Bolivia and Paraguay as neighbors in the west, Mato Grosso State in the north
and São Paulo, Minas Gerais and Paraná States in the east.
Cerrado is the predominant natural vegetation and the climate is mostly tropical
and high tropical of altitude (IBGE, 2002). The rainfall in the state is in average 1,500
mm per year with rainy summers and dry winters. The average temperature during
the year is 26º C (1minimum of 10 ºC and maximum temperature 40 ºC). The
economy of the state is based mainly on agricultural production. Mato Grosso do Sul
has the largest cattle herd of Brazil. Its geographic localization and efficient transport
systems make the state an important place to redistribute products from the Southern
and Southeastern to the North and Central western regions of Brazil.
Mato Grosso do Sul was considered a new agricultural frontier a few years ago
(FERRO, 2012). Currently, it is one of the most promising states in the forest sector.
The state increased its production from 536,976 cubic meters to 5,618,708 between
2000 and 2011 (IBGE, 2012). Eucalyptus is the predominant genus and the area
planted rose from 305 thousand to 970 thousand hectares between 2005 and 2010
(ABRAF,2012). Two of the most modern pulp mills are located in the state, which
account for 20 % of the national cellulose market (BRACELPA, 2011).
76
3.2.1.3 MAPITO region
The MAPITO region comprises the states of Maranhão, Piauí and Tocantins.
This region is considered the new Brazilian agricultural frontier; soybean and cattle
producers initiated their migration to the region in 1999 (NETTO, 2009)
Cerrado is the predominant vegetation in the region , the climate is tropical
(IBGE, 2002) with an average annual rainfall of 1,400 mm The dry season is severe
from December to April and the rainy months are from May to July. Thermometers in
MAPITO can reach 43º Celsius in the hottest period and 20º Celsius during the
winter.
According to Netto (2009), although the region presents several problems with
infrastructure, investors are optimist for future returns. In the forest sector, Eucalypt
plantations in MAPITO five-folded , from 125,738 in 2005 to 517,124 hectares in
2011. Most of these areas have not been harvested yet (IBGE, 2012), only the state
of Maranhão has commercialized wood in 2011 (151,798 cubic meters of
roundwood).
There are many uncertainties regarding Eucalypt production in the region. The
lack of knowledge of most productive species and silvicultural regime are some of the
challenges for research teams and investors in the region. On the other hand, the
macroeconomic scenario is favorable. The Brazilian government is encouraging
investment in infrastructure to make transportation more accessible in MAPITO.
Moreover, the access to the Atlantic Ocean in the north brings many logistic
advantages to exporting companies.
3.2.2 Land price historic
The bare land in the state of São Paulo is one of the most expensive in Brazil.
The land price of areas suitable for forest plantation production is on average eleven
times higher than in MAPITO and three times than in Mato Grosso do Sul. Despite
the higher prices, historical data of land prices did not show any sign of stability. In
the last 11 years, land prices increased 123 % in real terms in the state (Graph 3.5).
77
Graph 3.5 Land price historical data (real terms) in São Paulo, MAPITO and Mato Grosso do Sul States. Source: Informa Economics AGRAFNP.
Land prices in MAPITO and Mato Grosso do Sul State more than doubled in
real terms. MAPITO presented the highest increase (136 %) between 2002 and
2012, while Mato Grosso showed 101 % in the same period.
Land prices have demonstrated a similar behavior along the years and, unless
an unexpected economic crisis strikes, land prices tend to increase in the upcoming
years.
3.2.3 Financial criteria for investments in forest projects
Financial criteria give support to investors to allocate their capital to maximize
asset values. Furthermore, through financial criteria, investors can accept or reject
the project according to expected returns. Four economic criteria were used in this
research: (1) Net Present Value, (2) Internal Rate of Return, (3) Land Expectation
Value and, (4) Willingness to Pay for Land, considering future land value.
An essential aspect must be addressed before discussing the financial criteria:
the minimum accepted rate of returns (MARR). The MARR is the minimum
acceptable rate of return for a project that an investor is willing to accept
(KLEMPERER, 1996). The value used in this chapter is 11.35 %, which is based on
experts’ answers from the interviews applied in chapter 2 (topic 2.2.7 Minimum
Acceptable Rate of Return).
0
1500
3000
4500
6000
7500
9000
10500
12000
2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012
R$
/ha Sao Paulo
MAPITO
Mato Grosso do Sul
78
3.2.3.1 Net Present Value
Net Present Value (NPV) of a project is the current value of revenues subtracted
by the current value of costs (equation 3.1).
∑ ( ) ∑
( ) (3.1)
Where:
is the revenue in the year t;
is the cost in the year t;
i is the MARR; and
t is the year.
A project is viable if the NPV is greater or equal to zero. In other words, the
current value of revenues must be greater than or equal to the current costs in an
investor’s minimum acceptable rate of returns.
3.2.3.1 Internal Rate of Return
The Internal Rate of Return (IRR) is the discount rate that the NPV is equal to
zero (equation 3.2).
∑ ( ) ∑
( ) (3.2)
According to the IRR guidelines, a project is viable if its IRR is equal to or
greater than the MARR.
79
3.2.3.2 Land Expectation Value
Land Expectation Value (LEV) computes the maximum buyer’s willingness to
pay for bare land and, conversely, the minimum seller’s willingness to sell. LEV is
very popular among the forest economists. The LEV concept was developed by
Faustmann (1849) and calculated as the NPV of a perpetual series in an optimal
rotation (equation 3.3).
∑ ( ) ∑
( )
( ) (3.3)
Where:
is the revenue in the year t,
is the cost in the year t,
p is the forest cycle length,
t is the clear-cutting income.
3.2.3.3 Willingness to Pay for Land, considering future land value
Forest investors may want to sell their assets at the end or before the cutting
cycle. To calculate the land value at that time, the LEV equation (3.3) must be
adapted. According to Klemperer (1996), the Willingness to Pay for Land (WPL),
considering the future land value, is the current value of all revenues subtracting all
current costs including the land market value of bare land as revenue after clear –
cutting (equation 3.4).
( ) ∑ ( ) ∑
( ) ( ) (3.4)
Where:
is the revenue in the year t,
is the cost in the year t,
i is the MARR,
p is the forest cycle length,
FL is the future bare land value.
80
3.2.4 Revenues
Due to its importance in the current market and its versatility, Eucalyptus was
the genus chosen to simulate the cash flow analysis. The assumptions adopted of
the silvicultural aspects were: 1) spacing between the trees of 3 x 2 meters (1667
plants per hectare), 2) 1 % of mortality after the first plantation, 3) silvicultural regime
of 2 rotations of 7 years and 4) the second rotation production was considered 10 %
lower than the first due to coppice management influences (REZENDE;
OLIVEIRA;RODRIGUES, 2005).
3.2.4.1 Stumpage price
We selected energy and pulp for the timber market. The average timber prices
(Table 3.1) were collected from the Instituto de Economia Agrícola (IEA) in São
Paulo and by interviews with local producers and consumers in the other states.
Table 3.1 Stumpage price per region
Region R$.m-3
Sao Paulo 53.00
Mato Grosso do Sul 50.46
MAPITO 52.00
3.2.4.2 Volume Estimation
To accurately estimate productivity, we used the software SISEucalipto
developed by the Brazilian Agricultural Research Corporation (EMBRAPA).
SISEucalipto is a powerful forest management tool, which simulates forest
productivity based on characteristics of the site and the trees.
The SISEucalipto models are based on the permanent inventory in national
level of the specie Eucalyptus grandis. The simulation occurred in an integrated
model of site index (equation 3.5) and volume (equation 3.6).
81
( ( ) (3.5)
Where:
H is the total height
S is the Site Index
A is the tree age.
The volume model is:
(3.6)
Where:
V is the total volume in cubic meters,’
DBH is the Diameter at Breast Height, and
H is the total tree height.
The model runs based on assumptions 1, 2 and 3, presented in topic 3.2.4
Revenues and the site index values. The volume prognoses used a site index at the
base age 7 (SI7) provided by local producers (Table 3.2). The names of the local
producers cannot be provided due to a pre-accord between researchers and
interviewees.
Table 3.2 Site Index in meters in the study areas
Region Minimum Average Maximum
São Paulo 20 29 38
Mato Grosso do Sul 25 30 35
We did not use the site index value for the region of MAPITO in our research
because of the lack of information in the region. Consequently, we used the Mean
Annual Increment (MA) provided by local producers in the region as growth model
(Table 3.3).
Table 3.3 Mean Annual Increment in cubic meter in the region of MAPITO
Region Minimum Average Maximum
MAPITO 28 35 41
82
3.2.5 Costs
Local companies and institutes provided data on costs. The sources from
private companies were not quoted because of the agreement between researchers
and interviewees as in the revenue data source.
3.2.5.1 São Paulo State
Costs in the state of São Paulo were formulated based on field performance of
each operation carried out by local companies in their forest plantation (Table 3.4).
These field performances were then fitted into an accumulative statistic distribution
by means of the Maximum Likelihood Estimators method and after they were ranked
by the Chi Square Statistics. These methods are discussed in topic 3.2.6 Monte
Carlo Method. To estimate the cost per hour, we divided costs in Labor Hour per
Hectare (LHH) and Machine Hour per Hectare (MHH).
83
Table 3.4 Silvicultural operations in the state of São Paulo.
Silvicultural Operations
Opening internal and external roads
(Trail)
Limestone Aplication
Administration
Ant Control
Weed Control - Chemical
Subsoiling
Fertilization I (Base)
Plantation
Irrigation
Ant Control II
Ant Control III
Replantation
Irrigation
Weed Control - Between the lines -
Chemical
Fertilization II
Fertilization III
Administration
Road conservation
Weed Control - Between the lines -
Chemical
Weed Control - in the lines
Ant Control II
Fertilization II
3.2.5.1.1 Labor Cost
The cost of Labor Hour per Hectare was calculated based on the daily salary
provided by the Instituto Economico Agrícola. We assumed a work journey of 8 hours
per day and added more 100 % of the salary representing the Brazilian social and
labor taxes (Table 3.5).
84
Table 3.5 Labor Hour per Hectare
Labor R$/hour
Tractor Operator 12.72
Field Worker 10.13
3.2.5.1.2 Machinery Costs
Machinery cost were estimated according to MAKER, 2009. According to the
author, machinery costs are divided into fixed costs and variable costs.
3.2.5.2.1 Fixed Costs
Fixed costs (also called ownership costs) are defined as the cost computed
even when machinery is not operating. The fixed cost formation includes
depreciation, opportunity costs, taxes, insurance, housing and maintenance facilities
(equation 3.7).
(3.7)
Where:
TD is the total depreciation,
OP is the opportunity cost and,
TIH is the tax, insurance and housing.
3.2.5.2.1.1 Depreciation Cost
Depreciation is the cost resulting from use, obsolescence and age of machinery.
Before calculating the total depreciation, we needed to specify the salvage value.
The salvage value represents the value of machinery at the end of its economic
life, and is defined in the following equation:
85
(3.8)
Where:
SV is the Salvage Value;
CP is the Current Price and;
RFV is the Remaining Value Factor2
Once the salvage price is computed, the total depreciation value is calculated
according to the following equation:
(3.9)
Where:
TD is the total depreciation,
PP is the purchase price and,
SV is the salvage value.
3.2.5.2.1.2 Opportunity Cost
Opportunity cost of machinery is the cost of any activity in the farm business
measured in terms of value of the next best alternative. The opportunity cost was
calculated as Capital Recovery, which means the terminating equal annual revenue
required to justify the initial investment in machinery (equation 3.10) (Kleperer,1996,
MAKER, 2009).
( ( ) ) ⁄ (3.10)
Where:
CRV is the capital recovery value,
PP is the purchase price of machinery,
i is the interest rate,
n the estimated life of machinery3 and,
SV the salvage value.
2 The Remaining Value Factors (RVF) was derived from MAKER, 2009, p.4.
3 The estimated life was computed according to the American Society of Agricultural Engineers.
Source: ASAE Standards, ASAE D497.4, Agricultural Machinery Management Data, St. Joseph American Society of Agricultural Engineers, 2003. p. 377.
86
3.2.5.2.1.3 Taxes, insurance, housing (TIH)
We used a value of 1 % of the machine purchase price to represent the TIH cost
as other papers used (MAKER, 2009; PRATA, 2012).
3.2.5.2.1.4 Variables Costs
The variable costs (operating costs) are the costs computed when machinery is
operating in the field. It comprises costs with fuel and repairs. The fuel cost is
computed through the following equation:
(3.11)
Where:
F is the fuel cost,
EP is the engine power,
0.163 is the consumption factor for diesel engines4 and,
FP is the fuel price in reais.
The repair cost is defined by the equation 3.12:
(3.12)
Where:
RP is the repair cost,
PP is the purchase price,
RC is the repair factor5 and,
EL is the estimated machinery life
4 The consumption factor for diesel engines was provided by GONÇALVEZ, 2002.
5 The machinery repair factors were estimated according to the American Society of Agricultural
Engineers. Source: ASAE Standards, ASAE D497.4, Agricultural Machinery Management Data, St. Joseph American Society of Agricultural Engineers, 2003. p. 377.
87
3.2.5.2 MAPITO and Mato Grosso do Sul State
Unlike for the state of São Paulo, we did not have access to the operational
performance in the states of MAPITO and Mato Grosso do Sul. Therefore, the
operational costs of Mato Grosso do Sul State (Table 3.6) and the states of MAPITO
(Table 3.7) were collected as monetary values.
Table 3.6 Operation list of the state of Mato Grosso do Sul
Operation
Site Preparation
Planting
Weeding
Fertilizing
Weeding & Fertilizing
Weeding II
Fertilizing II
Forest Protection
Administration
Table 3.7 Operation list of the MAPITO region
Operation
Site Preparation,
Planting
Administration
Weeding, Etc.
Maintenance/Protection
88
3.2.5.3 Land Price
Land prices for the states of MAPITO and Mato Grosso do Sul were collected
from the annual report AGRIANUAL, 2013, and from the Instituto de Economia
Agricola (IEA) for the state of São Paulo data set.
The land category was selected by different means in the study areas. In the
São Paulo state database, we collected the bare land price of forest plantation areas.
We considered the land use changes already stable in the state and the areas with
agricultural or cattle production would not change to Eucalypt production in the long-
term.
The opposite scenario is observed in the MAPITO region. Due to changes in
land use, the bare land prices selected were the degraded, low productive pasture,
low productive agriculture areas and green field areas. In the Mato Grosso do Sul
State, degraded and low productive pasture; low productive agricultural and forest
plantation areas were selected as prices for bare land.
3.2.5.3.1 Land Opportunity Cost
The land opportunity cost concept is the same as discussed previously in topic
3.2.5.3.1 Opportunity Cost for machinery costs. The land opportunity cost is the
amount that investors foregone to make in other activity. The land opportunity cost
was calculated according to the equation 3.13 (SILVA, M. L. S. et al., 2008):
(3.13)
Where:
LOP is the land opportunity cost,
CP is the current land price and,
i is the interest rate.
The land opportunity cost is added to the cash flow analysis as an annual cost
(leasing cost).
89
3.2.5.3.1 Land price speculation scenarios
As demonstrated in topic 2.3.1 Willingness to Pay for Land, considering the
future land value, the investor may eventually desire to keep the land for a
determinate period. In this scenario, the land acquisition is computed as cost in year
zero and as revenue at the end of the investment cycle (14 years), that is, when the
investor decides to sell the land. To evaluate the impact of this future land value,
three scenarios were assumed during the production cycle (14 years):
1) The land price will have real annual increase rates as shown in topic 2.2 (12.29
% in São Paulo, 13.57 % and 10.16 % in MAPITO and Mato Grosso do Sul State,
respectively).
2) The land price will keep constant real price in the next 14 years.
3) The land price will decrease at average negative rates occurred in each region
in the last 10 years (-1.3 % in São Paulo,-3.4 % in MAPITO and -4.1 % in Mato
Grosso do Sul State).
3.2.6 Monte Carlo Method
The Monte Carlo Method is used to simulate the various sources of uncertainty
that affect returns of the investment (in this research the returns were measured by
LEV, NPV, and WPL). The results are composed of a random simulation of the input
values according to their statistical distribution function shape.
This method is largely used in financial and risk analysis. We used the software
@Risk6 to perform the Monte Carlo Simulation.
3.2.6.1 Input Statistical Distributions
The input statistical distributions were defined according to the data availability.
Except for the silvicultural operations in the state of São Paulo, the other statistical
distributions of input were assumed as a triangular behavior (Table 3.8) composed by
the maximum, minimum and most likely value. Alternatively, to define de statistical
6 More information about the software available at http://www.palisade.com/risk/5/tips/en/gs/.
90
distribution in silvicultural operations in the state of São Paulo, we utilized the
Maximum Likelihood Estimators Methods and the Chi-Square test.
Table 3.8 Factor distributions assumed as triangular
Inputs
Volume in first and second rotation
Land Price
Operational cost in MAPITO and MS
3.2.6.2 Maximum Likelihood Estimators (MLEs)
The MLEs methodology was used to fit the distribution of the operational
performance in São Paulo State. The MLEs of a distribution are the function
parameters that maximize the probability to obtain a given data set. The likelihood
expression of is defined as:
∏ ( ) (3.14)
Where:
L is the likelihood,
are the sample values and,
are the variables.
The MLE that maximize the L is the derivate of L due to α:
= 0 (3.15)
3.2.6 .3 Chi – Square test
The Chi-Square test is used to measure the goodness of fit between the
observed and expected outcome frequencies. This test is defined by the following
equation:
∑( )
( ) (3.16)
91
Where:
is the observed distribution and,
is the expected (tested) distribution.
The best distribution is the one where the Chi-Square is the minimum.
3.2.7 Sensitive Analysis
To evaluate the effect of some specific variables, we performed a sensitive
analysis by keeping fixed parameters and simulating different outputs in the cash
flow analysis. The fixed parameters were chosen according to their influence in the
result of the financial criteria. The financial criteria and their respective parameters
are:
1) NPV and IRR : land price, volume, stumpage price, sum of current operational
costs
2) LEV: stumpage, volume, sum of current operational costs.
3) WPL: considering future land value: Land price, volume, stumpage price, sum of
current operational costs and expected annual valorization of the land. The land
price, volume and stumpage price were simulated in three scenarios.
The sensitive analyses were performed within a fixed range of values (Table
3.9). This range was divided into 20 steps and for each step, 1,000 combinations
were run, thereby totalizing 20,000 simulations for each parameter.
Table 3.9 Parameters range used in the sensitive analysis.
Parameters São Paulo MAPITO Mato Grosso do Sul
Max Min Max Min Max Min
Land price (R$.ha-1
) 18,181.80 2,280.20 2,716.66 173.33 12,433.30 266.70
Stumpage Price (R$.m3) 60.00 45.00 60.00 45.00 60.00 45.00
Volume (m3.ha
-1) 417.70 104.00 287 182 359.20 180.10
Sum of the present
operational cost (R$.ha-1
) 7,428.64 6,045.32 7,882.67 6,255.62 6,016.58 4,362.20
Expected Valorization (%) 12.29 -1.30 13.57 -3.40 10.6 -4.10
92
In the final part of the sensitive analysis, we used the average outputs, e.g., the
average NPV, to compare results.
3.3 Results And Discussion
This topic will cover firstly the aspects related to revenues and costs. We will
discuss the yield model, the statistic distribution for the silvicultural operations costs
and land price values. Finally, we will present the financial criteria analysis and the
sensitivity analysis of the main aspect that influenced the return of investment in each
region.
3.3.1 Revenues
3.3.1.1 Yield models
As the same model (EMBRAPA) was applied to the states of São Paulo and
Mato Grosso do Sul, productivity increased directly proportional to the Site Index (SI)
value (Graph 3.6).
Graph 3.6 Eucalypt yield models in the states of São Paulo and Mato Grosso do Sul according to different Site Indexes
The MAPITO region had a simpler model and showed a linear growth (Graph
3.7):
93
Graph 3.7 Eucalypt yield models in the MAPITO region.
On average, sites in Mato Grosso do Sul State had higher production than the
other regions (Table 3.10). The state of São Paulo had the highest stand deviation
(the coefficient of variation was 25 %) while in the MAPITO region and Mato Grosso
do Sul State, the coefficient of variation was 7% and 13 %, respectively.
Table 3.10 - Volume in the seventh year in m³.ha-1 per region
Total Volume in m³ Mean Annual Increment
Rotation Category MAPITO
Mato Grosso
do Sul
São
Paulo MAPITO
Mato Grosso
do Sul
São
Paulo
First
Minimum 182.00 180.10 104.30 26.00 25.73 14.90
Mean 245.00 266.30 248.40 35.00 38.04 35.49
Maximum 287.00 359.20 417.70 41.00 51.31 59.67
Standard
Deviation 18.55 36.56 64.04 2.65 5.22 9.15
Second
Minimum 163.80 162.09 93.87 23.40 23.16 13.41
Mean 220.50 239.67 223.56 31.50 34.24 31.94
Maximum 258.30 323.28 375.93 36.90 46.18 53.70
Standard
Deviation 16.70 32.90 57.64 2.39 4.70 8.23
The range of volumes found for the state of São Paulo covered the values
observed in the literature. Simões et al.(1980) affirmed that yield of Eucalyptus
94
grandis could reach 471,88 steres.ha-1 on the seventh year, equivalent to 330 m3.ha-1
7,in the region near the municipality of Itupeva (Southeastern São Paulo State).
Gonçalves et al. (1990) studied the relation between SI and soil characteristics for
Eucalyptus grandis in several sites of São Paulo State. The authors found a yield
range between 13.28 to 32.8 m3.ha-1 of average annual increase. Bôas et al. (2009)
modeled the volume of different species in the region around the municipality of
Marília (center region of São Paulo State) and affirmed that Eucalyptus grandis
plantations can yield an average increase of 31 m3.ha-1.year-1.
The other research studies demonstrated a similar Eucalypt yield model in the
state of Mato Grosso do Sul. Silveira (2009) interviewed local producers and
observed an MAI range between 175 and 301 m3.ha-1 in Eucalypt plantations with
seven years of age.
Forest plantations were recently established in the MAPITO region and do not
provide enough database to model yield. However, comparing to other regions
occupied by the same vegetation cover (Cerrado), Morais (2006) studied the yield of
clonal Eucalypt in the Northwest of Minas Gerais State, and obtained the volume
374,31 m3.ha-1 in plantations with 7 years of age .
The yield models proposed in this research attempted to capture the average
production in the regions of MAPITO, São Paulo and Mato Grosso do Sul States. T
Literature results provided an idea about the model precision. Nevertheless, to
achieve more specific results, it is necessary to develop local yield models by
investigating soil conditions and performing a complete statistical analysis based on
a forest inventory database.
7 In this research, we used 0.7 as factor of conversion volume in steres to cubic meter (SBS, 2008)
95
3.3.2 Cost
3.3.2.1 Silvicultural Operations
Most companies, which have silvicultural operations data, considered the
operations performance strategic for their planning and market competition.
Therefore, they preferred to provide the maximum, minimum and most likely values
for a given operation rather than the complete database. We used these data to
assume a triangular distribution in the states of MAPITO and Mato Grosso do Sul
(Table 3.11 and 3.12).
Table 3.11 - Cost of silvicultural (R$.ha-1
) operations in the MAPITO states
Name Distribution Min Mean Max Median Mode Std
Dev
Administration / Triangular 100.00 133.33 180.00 131.01 120.00 17.00
Maintenance/
Protection Triangular 160.00 188.00 216.00 188.00 188.00 11.43
Site Preparation,
Planting Triangular 3690.00 4340.67 4992.00 4340.50 4340.00 265.77
Weeding, Etc. Triangular 562.00 660.67 760.00 660.50 660.00 40.42
96
Table 3.12 - Cost of silvicultural (R$.ha-1
) operations in the state of Mato Grosso do Sul
Name Distribution Min Mean Max Median Mode Std Dev
Administration
Triangular 100.00 133.33 180.00 131.01 120.00 17.00
Fertilizing I Triangular 350.00 606.67 800.00 618.33 670.00 94.55
Fertilizing II Triangular 160.00 226.67 280.00 229.28 240.00 24.94
Maintenance/
Protection Triangular 50.00 64.67 80.00 64.51 64.00 6.13
Maintenance/
Protection Triangular 50.00 64.67 80.00 64.51 64.00 6.13
Planting Triangular 850.00 976.67 1080.00 981.34 1000.00 47.67
Protection II Triangular 36.00 49.33 72.00 48.00 40.00 8.06
Site Preparation Triangular 480.00 646.67 800.00 649.71 660.00 65.49
Weeding Triangular 100.00 173.33 300.00 165.84 120.00 44.97
Weeding I Triangular 400.00 633.33 1000.00 612.70 500.00 131.23
On the other hand, we had access to a full database of silvicultural operations in
the state of São Paulo, except for data on administration, replanting operation costs
and opening primary and secondary roads.
The silvicultural operations data in the state of São Paulo were fitted according
to MLEs and selected the best distribution by the Chi Square test (Table 3.13).
97
Table 3.13 - Cost of silvicultural (R$.ha-1
) operations in the state of São Paulo
Name Distribution Min Mean Max Median Mode Std
Dev
Opening primary and
secondary roads8
- 818.30 818.30 818.30 818.30 818.30 818.30
Administration Triangular 100.00 133.33 180.00 131.01 120.00 17.00
Ant Control Log-Logistic 22.13 24.71 34.53 23.91 22.82 2.44
Ant Control II Inverse
Gaussian 13.96 19.45 33.80 17.84 13.99 5.00
Ant Control III Inverse
Gaussian 9.46 14.95 29.30 13.34 9.49 5.00
Fertilization I (Base) Log-Normal 365.43 409.57 598.80 394.24 365.63 45.10
Fertilization II Log-Logistic 235.46 276.07 429.77 267.68 256.77 31.08
Fertilization II -
Maintenance I Log-Logistic 235.45 276.07 429.75 267.68 256.29 31.10
Fertilization II -
Maintenance II Log-Logistic 235.46 276.07 429.51 267.68 256.77 31.08
Fertilization III Log-Logistic 156.86 209.12 335.12 204.20 195.16 28.50
Irrigation Normal 20.86 40.49 68.01 39.35 33.53 12.00
Limestone Application Normal 219.47 314.90 436.99 312.43 305.89 51.35
Manual Mowing Normal 8.10 23.02 34.02 23.46 24.65 6.30
Plantation Triangular 515.82 536.16 554.42 536.62 538.13 8.00
Replanting Triangular 12.24 28.83 38.35 29.92 38.28 6.65
Subsoiling Weibull 97.02 149.58 336.59 140.78 98.21 40.60
Weed Control - Between
the lines – Chemical
Inverse
Gaussian 189.52 319.83 725.79 278.04 190.09 123.90
Weed Control - Chemical Logistic 106.82 128.78 146.57 129.16 129.28 9.00
Weed Control - Chemical II Logistic 66.82 88.78 106.57 89.16 89.28 9.03
Weed Control - in the lines Logistic 76.37 103.06 119.38 103.87 105.67 9.20
8 Source: PRATA, G. A. Estimação do risco e do valor da floresta para fins securitários no
Brasil.2012. Thesis (Mestrado em Recursos Florestais) – Escola Superior de Agricultura “Luiz de
Queiroz”, Universidade de São Paulo, Piracicaba,2012.
98
3.3.2.2 Land Price
Land price values are composed by a range of different uses in the states of
MAPITO and Mato Grosso do Sul and areas suitable for forest plantation in the state
of São Paulo. Moreover, the land price distribution was assumed as triangular ; the
highest land price value (18,181.82 R$.ha-1) was found in São Paulo State and the
lowest values (173.82 R$.ha-1 and 266.67 R$.ha-1) in areas occupied by natural
vegetation in the states of MAPITO and in degraded pasture in the state of Mato
Grosso do Sul, respectively (Table 3.14).
Table 3.14 - Land price (R$.ha-1
) statistical distribution
State Distribution Min Mean Max Std Dev Coefficient of
Variation
São Paulo Triangular 2,280.24 10,411.41 18,181.82 3,248.40 31.20%
MAPITO Triangular 173.33 1,385.49 2,716.67 520.86 37.59%
Mato Grosso do Sul Triangular 266.67 5,778.16 12,433.33 2,516.21 43.55%
Land prices in the state of São Paulo are on average seven times higher than in
MAPITO and 1.8 times greater than in Mato Grosso do Sul. This difference increases
in the minimum values twelve times over the land price in MAPITO and eight times in
relation to Mato Grosso do Sul State.
Even though the state of São Paulo showed the highest standard deviation, the
coefficient of variation (CV) was the lowest (31.20%), indicating lower mean variation
than the CV observed in the other regions. In other words, the likelihood to find the
average value is greater in the land market of the São Paulo State.
99
3.3.3 Financial criteria
Once the statistical distribution from the revenues and cost was fitted and set
into a discounted cash flow, the Monte Carlo simulation was performed for each
financial criterion.
3.3.3.1 Net Present Value (NPV)
Among the three regions analyzed, only MAPITO presented NPV greater than
zero on average, that is, the only region that the average return of investment could
be classified as accepted and feasible at 11.23 % of discount rate (Table 3.15).
Table 3.15 - Descriptive statistics of the Net Present Value (R$.ha-1
)
Region Min Mean Max Median Mode Std Dev
MAPITO -2,762.39 130.21 3,100.60 141.65 262.16 855.16
Mato Grosso do Sul -12,326.03 -1,454.82 7,704.93 -1,311.91 -994.79 3,325.48
São Paulo -18,120.69 -6,738.99 5,131.96 -6,758.81 -5,824.14 3,679.80
Furthermore, MAPITO showed less risk, the lowest standard deviation value
(858.57 R$.ha-1) and distribution in the histogram (Graph 3.8). Conversely, the states
of São Paulo and Mato Grosso do Sul indicated the extremes values. São Paulo
presented the lowest NPV values (-18,120.69 R$.ha-1), while Mato Grosso do Sul
(7,704.93 R$.ha-1) had the highest NPV.
100
Graph 3.8 - Net Present Value histogram
The results indicated that the likelihood to have a viable forest project in São
Paulo State is lower than in Mato Grosso do Sul and MAPITO. Only 3.4 % of the
NPV distribution is greater than zero in São Paulo State. The likelihood found in Mato
Grosso do Sul and MAPITO was 31.5 % and 52.8 % greater than in São Paulo,
respectively.
3.3.3.2 - Internal Rate of Return (IRR)
The IRR showed similar results to those found for the NPV criteria. Only the
MAPITO region presented IRR higher than the minimal interest of return (11.35%)
indicating economic feasibility.
Table 3.16 - Descriptive statistics of the Internal Rate of Return
Region Min Mean Max Median Mode Std Dev
MAPITO 5.00% 11.58% 17.55% 11.63% 11.78% 1.69%
Mato Grosso do Sul -10.37% 9.00% 24.49% 9.22% 8.43% 5.42%
São Paulo -26.16% -0.76% 19.47% -0.29% 2.16% 7.14%
Volatility was also favorable for the MAPITO region. The standard deviation was
lower than in the other regions as observed in the NPV results. In certain
101
combinations, however, the states of Mato Grosso and São Paulo can provided
greater IRR, 24.49 % and 19.47 % respectively.
The histogram showed the same rate of feasibility for the three regions, as
observed for the NPV (Graph 3.9).
Graph 3.9 - Internal Rate of Return histogram
3.3.3.3 Land Expected Value (LEV)
3.3.3.3.1 General Analysis
The results indicated Mato Grosso do Sul as the most favorable region for
Eucalypt production accourding to the LEV criteria. The state was the only area that
showed positive LEV, even in a less profitable combination and lower coefficiente of
variation (Table 3.17).
102
Table 3.17 - Descriptive statistics of Land Expected Value (R$.ha-1
)
Region Min Mean Max Median Mode Std Dev Coefficient
of Variation
MAPITO
-
1,041.76 1,754.99 4,759.14 1,769.57 1,684.23 914.20 52%
Mato Grosso do Sul 1028.97 5166.296 9571.674 5151.94 5134.69 1625.148 31%
São Paulo
-
3,953.44 3,268.41 10,818.93 3,187.90 2,684.67 2,940.33 90%
São Paulo and MAPITO presented minimum negatives values. These results
indicated that landuse for forest production is not adequate in some occasions in
both states. Nevertheless, the likelihood to obtain these results is not high, given that
85.4 % of the combinations in the state of São Paulo and 97.2 % in the states of
MAPITO resulted in LEV above zero (Graph 3.10).
Graph 3.10 - Land Expected Value Histogram
103
3.3.3.3.2 Land Bid Prices
In a land bid negotiation, LEV is one of the tools for the appraisal the timberland
value.LEV values indicate the minimum possible price offered by the buyer and the
maximum possible price proposed by the seller. Therefore, people involved in the
negotiation must be aware of the land price value in the market to validate LEV
results and to analyze the economic viability of the project. The project is considered
viable if its LEV is equal to or greater than the market land price. For this analysis, we
considered market land prices in Table 3.9 (topic 3.3.2.2 Land Price).
Despite having the highest LEV values, Mato Grosso do Sul did not show the
highest feasibility of projects, comparing the average land price (5,778.16 R$.ha-1),
35 % of LEV distribution results were greater than the market value. The states of
MAPITO presented the highest rates, 65.5 % of the LEV simulated are higher than
the average land price ( 1,385.49 R$.ha-1), while the state of São Paulo presented
the lowest, where only 0.1 % of its LEV were higher than the average market land
price (10,411.41 R$.ha-1).
Moreover, the state of São Paulo showed the worst scenario for the minimal and
maximum market land prices, where 62.1 % was higher than the minimum (2,280.24
R$.ha-1) and none of the combination presented LEV higher than the maximum land
price ( 18,181.82 R$.ha-1). On the other hand, the state of Mato Grosso do Sul
presented the best scenario for minimal values, where 100 % of LEV distribution
were higher than the market price ( 266.67 R$.ha-1), and the worst scenario for
maximum values, similar to São Paulo State, none of the LEV combinations was
creater than the maximum market value (12,433.33 R$.ha-1). The LEV results for the
MAPITO region were the only to surpass the maximum market value, where 15.7 %
of the LEV simulations were greater than 2,716.67 R$.ha-1 in the region.
104
3.3.3.4 Willingness to Pay for Land (WPL), considering future land value
The WPL ,considering future land value, computes the land acquisition at the
beginning of the project as part of costs and, at end of the planning horizon, as part
of revenue. The following topics will discuss the different scenarios for future land
value.
3.3.3.4.1 Land price will increase in real terms:
The region of MAPITO had the highest annual land price rate among the
regions studied, where the land price increased 13.57 % per year in the last 10
years. In the same period, land prices increased 12.29 % and 10.16 % per year in
São Paulo and Mato Grosso States, respectively.
In this scenario, the results showed a drastic difference between the current
NPV and WPL, considering the future land value. Despite having the lowest risk
(lowest standard deviation) and the highest minimum value, the region of MAPITO
did not show the most attractive values according to these criteria and scenario.
Conversely, Mato Grosso do Sul and São Paulo States had economically feasible
projects according to the mean values (Table 3.18).
Table 3.18 - Descriptive statistics of WPL (R$.ha-1
), considering an increase in the future land price
Region Min Mean Max Median Mode Std Dev
MAPITO -1,477.61 871.79 3,339.56 883.18 741.61 738.32
Mato Grosso do Sul -3,778.75 1,427.49 6,451.20 1,445.47 1,465.74 1,686.36
São Paulo -7,858.97 1,138.69 10,881.06 1,043.92 1,078.45 3,234.81
The rate of the feasible projects also increased in the states of São Paulo and
Mato Grosso do Sul. The likelihood to have NPV greater than zero raised from 34.9%
to 79.3 % in the state of Mato Grosso do Sul, 3.4 % to 62.5% in the state of São
Paulo and 56.2% to 87.0 % in the MAPITO region (Graph 3.11).
105
Graph 3.11 - Histogram of WPL (R$.ha-1), considering an increase in the future land price
3.3.3.4.2 Land price will keep the same level in real terms
As expected, this scenario presented less attractive results for investors than
the previous item. Moreover, the results showed distinct attractiveness levels among
the regions. MAPITO was the most attractive region according to the mean value
(287.47 R$.ha-1) and in Mato Grosso do Sul, WPL surpassed the current value of the
state of São Paulo by 335.84 R$.ha-1 (Table 3.19).
Table 3.19 - Descriptive statistic of the WPL (R$.ha-1), considering zero increase in the future land price
Region Min Mean Max Median Mode Std Dev
MAPITO -2,492.05 287.47 2,929.73 301.88 52.81 821.74
Mato Grosso do Sul -7,882.45 -476.03 6,304.83 -409.59 -430.47 2,340.07
São Paulo -14,604.92 -2,838.05 8,693.34 -2,871.25 -2,635.16 3,898.76
The likelihood to have a feasible project decreased as well. The highest
decrease was observed in the state of São Paulo, where the likelihood dropped from
62.4 % to 23.5 % while in MAPITO, the drop was from 87.0 % to 63.7 %. Despite
106
showing lower likelihood, Mato Grosso still had the highest values, followed by São
Paulo and MAPITO (Graph 3.12).
Graph 3.12 - Histogram of WPL (R$.ha-1), considering zero increase in the future land price
3.3.3.4.3 Land price will decrease annually at the same rate as the average of the
negative rates observed in each region in the last 10 years.
Among the scenarios proposed, by far this is the least favorable. We assumed
an annual decrease of 1.3 %, 3.4 % and 4.1 % for São Paulo, MAPITO and Mato
Grosso do Sul, respectively, for the next 14 years.
The expected mean is below zero for every region and the likelihood to have a
feasible project is the lowest among the scenarios. MAPITO was the only region that
showed positive average (141.06 R$.ha-1). São Paulo and Mato Grosso did not
present likelihood for a feasible project . Nonetheless, the maximum values
demonstrated excellent return of investments in all the scenarios. São Paulo showed
the highest values for return of investments (9,969.05 R$.ha-1) (Table 3.20).
107
Table 3.20 - Descriptive statistic of WPL (R$.ha-1), considering a decrease in the future land price
Region Min Mean Max Median Mode Std Dev
MAPITO -2,745.79 141.06 3,092.670 152.49 298.00 856.26
Mato Grosso do Sul -9,811.45 -1,212.31 6,670.560 -1,135.82 -1,161.09 2,615.31
São Paulo -15,434.95 -3,258.70 9,969.05 -3,260.17 -2,490.02 4,013.86
The rate of feasible projects decreased in all studied states. Moreover, in the
state of Mato Grosso do Sul, the rate decreased to 34.4 % (Graph 3.13), which is not
only the lowest among the scenarios proposed for the state, but also, lower than the
rate computed in the net present value scenario (34.9 %) (Considering land
opportunity cost) in topic 3.3.3.1.
Graph 3.13 - Descriptive statistic of WPL (R$.ha-1), considering a decrease in the future land price.
108
3.3.4 Sensitive Analysis.
We carried out the sensitive analysis for NPV, IRR, LEV and WPL, considering
the future land price in the studied areas. For each financial criterion, we selected
specific parameters discussed in topic 2.7 Sensitive Analysis and analyzed their
influence in the results.
3.3.4.1 Net Present Value (NPV)
In the NPV criteria, the region of MAPITO showed a distinct behavior from the
other regions analyzed. The difference between the minimum and maximum NPV
indicated lower influence of the land leasing on the results. However, the final volume
including the stumpage price and sum of the operational current costs had higher
impact on NPV results in the MAPITO region (Table -3.21).
109
Table 3.21 - Sensitive analysis of the Net Present Values
MAPITO
Parameter
Net Present Value
(R$.ha-1
)
Average value in
the region NPV = 0 MIN MAX
Land Leasing (R$.ha-1
.year-1
) 143.75 186.00 - 171.59 -1,056.51 1,211.06
Stumpage Price (R$.m-3
) 52 50.00 - 51.00 -1,009.48 1,432.79
Volume (m³.ha-1
) 245 242 - 237 -1,986.40 1,677.00
Sum of the Operational Current
Costs (R$.ha-1
) 7,101.12
7,428.24 -
7,037.28 -196.82 976.0624
Mato Grosso do Sul
Average value in
the region NPV = 0 MIN MAX
Land Leasing (R$.ha-1
.year-1
) 526.01 539.02 - 466.34 -7,064.92 3,781.70
Stumpage Price (R$.m-3
) 50.45 56 -2,115.42 587.17
Volume (m³.ha-1
) 266.3 302.64 - 293.21 -4,125.68 1,937.98
Sum of the Operational Current
Costs (R$.ha-1
) 5,072.11
4116.60 -
3799.95 -2076.24 -492.93
São Paulo
Average value in
the region NPV = 0 MIN MAX
Land Leasing (R$.ha-1
.year-1
) 1.222.24 353.79 - 258.80 -
13,666.55 509.86
Stumpage Price (R$.m-3
) 53 93.17 - 91.31* -8,117.27 -5532.75
Volume (m³.ha-1
) 248.4 447.57 - 443.21* -
12,172.55 -1017.23
Sum of the Operational Current
Costs (R$.ha-1
) 5,770.79 - -7650.14 -6465.92
On the other hand, land leasing prices had a higher impact on NPV in the states
of São Paulo and Mato Grosso do Sul. Land leasing prices was the only parameter
capable of making the forest project feasible in the state of São Paulo. Furthermore,
forest projects in the state of São Paulo were not attractive using the current
stumpage price offered in the market (52 R$.ha-1) or the maximum production
110
assumed in this research (417 m3 in the first rotation). Stumpage price needed to
increase 38.31 R$.m-3 and production 26.12 m3 to make projects feasible.
Furthermore, the worst aspect was the sum of the operational current costs. Even the
most efficient operation process (the less expensive) was not capable of making NPV
average greater or equal to zero in the state.
As occurred in the state of São Paulo, where stumpage price made NPV equal
to zero, Mato Grosso do Sul showed a higher value than offered in the market (
50.46 R$.ha-1). Conversely, in the MAPITO region, stumpage price was lower than in
in the market (52 R$.ha-1).
The Mato Grosso do Sul State was more attractive compared to the regions
analyzed. Land leasing in the state could be higher and still be profitable, while
MAPITO showed the lowest land leasing prices.
3.3.4.2 Internal Rate of Return (IRR)
The IRR showed the same behavior as NPV in the results for the sensitive
analysis. Nevertheless, the parameters that made IRR equal to the minimal accepted
rate (11.35 %) showed slightly different values (Table 3.22) These different values
are due to the distinguish combination in the simulation performance.
111
Table 3.22 -´Sensitive analysis of Internal Rate of Return
MAPITO
Parameter Internal Rate of
Return (%)
Average value in the
region IRR = 11,35% MIN MAX
Land Leasing (R$.ha-1
.year-1
) 143.75 171.69 9.27% 13.75%
Stumpage Price (R$.m-3
) 52 51.31 9.20% 13.96%
Volume (m³.ha-1
) 245 242.78 6.91% 14.42%
Sum of the Operational
Current Costs (R$.ha-1
) 7,101.12 7428.24 -7037.28 11.03% 13.31%
Mato Grosso do Sul
Average value in the
region IRR = 11,35% MIN MAX
Land Leasing (R$.ha-1
.year-1
) 526.01 466.34 -0.023 20.00%
Stumpage Price (R$.m-3
) 50.45 56.84 0.067 12.48%
Volume (m³.ha-1
) 266.3 302.64 0.01 15.01%
Sum of the Operational
Current Costs (R$.ha-1
) 5,072.11 4116.60 - 3799.95 0.074 10.45%
São Paulo
Average value in the
region IRR = 11,35% MIN MAX
Land Leasing (R$.ha-1
.year-1
) 1222.64 258.85 -0.095 11.81%
Stumpage Price (R$.m-3
) 53 95 - 93.15 -0.04 1.67%
Volume (m³.ha-1
) 248.4 443.21 - 4,38.84 -0.139 10.13%
Sum of the Operational
Current Costs (R$.ha-1
) 5,770.79 - -0.035 -1.16%
3.3.4.3 Land Expectation Value (LEV)
The production volume parameter had the greatest impact on LEV criteria. In
the state of São Paulo, LEV can vary 14,338.31 R$.ha-1 (from -3,715.61 to 10,622.70
R$.ha-1) depending on the volume produced (Table 3.23). Furthermore, only the
highest volume performed (417.70 m3.ha-1 at the end of the first rotation) could make
LEV equal to the average land price offered in the market in the state (R$ 10,411.41
R$.ha-1).
112
Table 3.23 - Sensitive analysis of Land Expectation Value
MAPITO
Parameter Net Present Value
(R$.ha-1
)
Average value in the
region
LEV >= R$/ha
1.385.49 MIN MAX
Stumpage Price (R$.m-3
) 52 50.52 - 49.73 290 3,429.12
Volume (m³.ha-1
) 245 237.00 -231.00 -965.6 3,743.09
Sum of the Operational
Current Costs (R$.ha-1
) 7,101.12 7,142.40 621.92 2,782.01
Mato Grosso do Sul
Average value in the
region
LEV >= R$/ha
5,778.16 MIN MAX
Stumpage Price (R$.m-3
) 50.45 52.80 - 52.10 3901.67 7375.35
Volume (m³.ha-1
) 266.3 293.21 - 283.78 1317.97 9111.8
Sum of the Operational
Current Costs (R$.ha-1
) 5,072.11 0 -2668.57 -633.48
São Paulo
Average value in the
region
LEV >= R$/ha
10,411.41 MIN MAX
Stumpage Price (R$.m-3
) 53 85.78 - 85.78 1496.71 4818.67
Volume (m³.ha-1
) 248.4 417.7 -3715.61 10622.7
Sum of the Operational
Current Costs (R$.ha-1
) 5,770.79 781.96 2189.73 4199.89
Unlike the results for NPV, LEV was positive in the operational costs in the state
of São Paulo. The region of MAPITO showed more attractive return of investments
despite high costs, the maximum operational current cost proposed was 7,882.76
R$.ha-1, which is 740.27 higher than the minimum cost that make the project feasible.
On the other hand, in the state of Mato Grosso do Sul, lower operational costs were
not higher than land prices practiced in the market.
Stumpage price in this scenario was lower than in NPV criteria; however, prices
were higher than the market, except for the MAPITO region of. The highest
stumpage price was observed in São Paulo with 32.78 m3.ha-1 against the market
price 52 m3.ha-1.
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3.3.4.4 Willingness to Pay for Land, Considering Future Land Value
3.3.4.4.1 Land price will increase in real terms.
The production volume parameter was most drastically impacted cash flow in
this scenario. São Paulo state showed the most influence of this parameter, where
final NPV ranged from -5,913.06 to 8,554.04 R$.ha-1 (Table 3.24).
Table 3.24 - Sensitive analysis of WPL, considering an increase in the future land price
MAPITO
Parameter Net Present Value (R$.ha-1
)
Average value
in the region NPV = 0 MIN MAX
Land Price (R$.ha-1
) 1266.48 3,842.98 - 3,749.12 602.66 1,316.79
Stumpage Price (R$.m-3
) 52 46.57 - 45.78 -163.34 2,278.91
Volume (m³.ha-1
) 245 215.15 - 209.63 -1,140.22 2,523.18
Sum of the Operational
Current Costs (R$.ha-1
) 7,101.12 8,052.91 – 7,967.79 90.26 1749.77
Mato Grosso do Sul
Average value
in the region NPV = 0 MIN MAX
Land Price (R$.ha-1
) 4634.47 9,231.56 – 8,591.21 -1,557.74 3,899.86
Stumpage Price (R$.m-3
) 50.45 43.68 - 42.36 443.93 3,146.55
Volume (m³.ha-1
) 266.3 227.23 - 217.80 -1,566.42 4,497.24
Sum of the Operational
Current Costs (R$.ha-1
) 5,072.11 6,534.16 – 6,482.41 483.14 2066.45
São Paulo
Average value
in the region NPV = 0 MIN MAX
Land Price (R$.ha-1
) 10,772.18 13,997.06 – 13,160.24 -1,938.47 4,359.35
Stumpage Price (R$.m-3
) 53 48.15 - 47.36 -650.06 2,704.12
Volume (m³.ha-1
) 248.4 236.08 - 219.57 -5,913.06 8,564.04
Sum of the Operational
Current Costs (R$.ha-1
) 5,770.79 7,834.64 – 7,699.30 670.677 1863.17
Surprisingly, the land price did not change NPV results as much as the other
parameters did in the MAPITO region, where NPV could range from 602.66 to
114
1,316.79 R$.ha-1, depending on the land price simulated. In the states of São Paulo
and Mato Grosso do Sul, however, operational current costs had the lowest influence
on the results.
The three studied areas could show less favorable values in the cash flow
analysis than in NPV analyzed in the previous topic and still have a feasible project,
according to the parameters studied. In the state of São Paulo the volume and
stumpage price decreased 48 % (from 447.57 to 236.08 m3.ha-1) and 47 % (from 93
to 48.15 R$.m-3), respectively, and operational costs were higher than the average
practiced in the market.
MAPITO had the most favorable values for the parameters volume in the cost
analysis. The region could manage higher operational costs (8,052.91 to 7,967.78
R$.ha-1) and lower productive levels (215.15 to 209.63 m3.ha-1) than the other
regions. In the land price parameter, São Paulo presented the best return of
investments despite higher costs for land acquisition (13,997.06 to 13,160.24 R$.ha-
1) and Mato Grosso showed the best return of investments, despite lower stumpage
prices.
3.3.4.4.2 Land price will keep at the same price in real terms.
As predicted, as the expected future value reduced, the values of land price and
operational cost decreased and volume and stumpage price increased to keep the
project still feasible in the three regions. The land price had the highest drop in the
MAPITO region, where the land price reduced 53 % (from 3,842. 98 to 1,779.52
R$.ha-1). Conversely, stumpage price had the highest increase (from 48 to 76.36
R$.m-3) in the state of São Paulo.
The land price and stumpage price demanded higher values than market prices
and lower operational costs in the state of São Paulo (Table 3.25). On the other
hand, MAPITO was the only region that showed higher value in the land price and
operational costs, and lower in the stumpage price and in the volume and while, in
the state of Mato Grosso do Sul only the stumpage price surpassed market prices.
115
Table 3.25 - Sensitive analysis of WPL, considering zero increase in the future land price
MAPITO
Parameter
Net Present Value
(R$.ha-1
)
Average value in
the region NPV = 0 MIN MAX
Land Price (R$.ha-1
) 1266.48 1779.52 - 1645.65 -748.21 1,230.78
Stumpage Price (R$.m-3
) 52 50.52 - 49.73 -852.2 1,590.06
Volume (m³.ha-1
) 245 237.26 - 231.73 -1,829.09 1,834.31
Sum of the Operational Current
Costs (R$.ha-1
) 7,101.12 7467.80 - 7052.91 -494.06 1,165.44
Mato Grosso do Sul
Average value in
the region NPV = 0 MIN MAX
Land Price (R$.ha-1
) 4634.47 5389.47 - 4749.13 -5,653.81 3,811.90
Stumpage Price (R$.m-3
) 50.45 53.68 - 52.89 -1,459.82 1,242.77
Volume (m³.ha-1
) 266.3 283.78 - 274.36 -3,470.08 2,593.58
Sum of the Operational Current Costs
(R$.ha-1
) 5,072.11 4749.93 - 4443.26 -1420.83 479.14
São Paulo
Average value in
the region NPV = 0 MIN MAX
Land Price (R$.ha-1
) 10,772.18 7301.75 - 6464.83 -8,883.46 3,488.12
Stumpage Price (R$.m-3
) 53 67.36 - 65.52 -4,626.79 -
1,272.67
Volume (m³.ha-1
) 248.4 318.63 -9,889.59 4,587.51
Sum of the Operational Current Costs
(R$.ha-1
) 5,770.79 3909.81 - 3518.82 -3,677.85 2,113.93
While the final volume had more influence on the state of São Paulo and in the
MAPITO region, the land price had more impact on the results of the Mato Grosso do
Sul. Additionally, the sum of operational current costs had less influence in the
MAPITO region and Mato Grosso do Sul State, while in the São Paulo State,
stumpage price did not affect as much as the other NPV parameters of.
3.3.4.4.3 Land price will decrease annually following the same average rate as the
negative rates.
116
This scenario indicated even lower results than the previous scenario. The
decrease in the expected future price demanded values more attractive for the
parameters analyzed. The parameter with the highest decrease was the sum of the
operational cost in the state of Mato Grosso do Sul, where costs decreased from
4,749.93 to 3,799.95 R$.ha-1. Conversely, the highest increase was found in the
parameter of stumpage price in the MAPITO region (from 50.52 to 57. 63 R$.m-3).
The volume had the greatest influence on NPV in the MAPITO region and São
Paulo State. The difference between the minimum and maximum NPV were
14,477.10 R$.ha-1 in São Paulo and 3.663.40 R$.ha-1 in MAPITO. In the state of Mato
Grosso do Sul, on the other hand, NPV results were mostly influenced by land price
acquisition (from -7,238.11 to 3, 77.92 R$.ha-1) (Table 3.26).
117
Table 3.26 - Sensitive analysis of WPL, considering zero increase in the future land price
MAPITO
Parameter Net Present Value (R$.ha-1
)
Average value in
the region NPV = 0 MIN MAX
Land Price (R$.ha-1
) 1,266.48 1,645.65 – 1,511.77 -1,035.25 1,212.53
Stumpage Price (R$.m-3
) 52 52.11 - 51.32 -998.65 1,443.61
Volume (m³.ha-1
) 245 242.78 - 237.26 -1,975.55 1,687.85
Sum of the Operational
Current Costs (R$.ha-1
) 7,101.12 7,467.79 – 7,052.91 -640.46 1,019.05
Mato Grosso do Sul
Average value
in the region NPV = 0 MIN MAX
Land Price (R$.ha-1
) 4,634.47 4,748.13 – 4,108.78 -7,238.11 3,777.92
Stumpage Price (R$.m-3
) 50.45 57.63 - 56.84 -2,196.07 506.51
Volume (m³.ha-1
) 266.3 312.06 - 302.6421 -4,206.31 1,857.34
Sum of the Operational
Current Costs (R$.ha-1
) 5,072.11 3,799.95 -2157.16 -573.85
São Paulo
Average value in
the region NPV = 0 MIN MAX
Land Price (R$.ha-1
) 10,772.18 6,464.83 – 5,627.90 -9,618.09 3,395.95
Stumpage Price (R$.m-3
) 53 69.21 -67.36 -5,047.69 -
1,693.59
Volume (m³.ha-1
) 248.4 351.65 - 335.14 -10,310.45 4,166.65
Sum of the Operational
Current Costs (R$.ha-1
) 5,770.79 3,518.82 - ,3127.84 -4098.78
-
2925.83
The stumpage price did not achieve the average value required by the market in
all the regions studied except in MAPITO. The simulation indicated that, on average,
land price should reach 8 and 22 %higher than the current market prices in the Mato
Grosso do Sul and São Paulo States, respectively.
In the MAPITO region and Mato Grosso do Sul State, land price was lower
value than the minimum required to make the project feasible. In the sum of
operational current costs, only the states of MAPITO had better values than practiced
in the market. As occurred in the scenario with no land price increase, the worst
118
return of investments was found in the state of São Paulo, where land prices did not
achieve the average value required by the market in all parameters analyzed.
3.3.4.4.4 Expected Valuation Analysis
In this topic, we present the influence of the expected valuation of land price on
the NPV criteria. The MAPITO region had the most attractive results. The land
provides a feasible project even depreciating 7 % per year (Table 3.27).
Table 3.27 - Sensitive analysis of WPL, considering the different speculation prices
Region NPV = 0 MIN MAX
MAPITO - 7.0 % 139.28 888.26
Mato Grosso do Sul 2.8 % -2.0 % -1,212.01 1,427.68
São Paulo 8.9 % - 8.1 % -3,258.70 1,138.84
The state of São Paulo showed the highest variation for this aspect (R$ -
3,258.70 to R$ 1,138.84 per hectare). The minimum increase in land price were
between 8.1 and 8.9 % per year to keep the project feasible in the state.
3.4 Discussion
One of the main objectives of this research was to investigate timberland
investments in traditional areas and in new agricultural frontiers in Brazil. The results
showed both negative and support some of the hypotheses tested. We predicted that
forest projects were not as feasible in traditional areas as in the new agricultural
frontiers due to land price; however, this was not completely true. Moreover, risk
aspects were attractive to all profiles of investors.
119
3.4.1 Land cost effect
The different scenarios of a forest project must be studied deeply by the
investors and their team, as well as criteria and methods used that may influence the
project feasibility. The way land price is incorporated into the cash flow analysis was
an important factor in the economic criteria analyzed in this chapter.
The results showed that the decision between purchasing and renting the land
was crucial for the viability of the project. The land price affected directly the return of
investments of the project in the three regions analyzed. The forest project was more
attractive in the Willingness to pay for Land (WPL), considering future scenarios, than
in the Net Present Value (NPV). Silva et al. (2008) discussed this effect and stated
that the land price is always higher when it is incorporated into the cash flow analysis
as an opportunity cost than when it is purchased at the beginning of the investments
and selling at the end expecting at least zero of real increase in the price land.
Berger and Santos, 2011 discussed land price effect in an economic analysis in
pine plantation in the south of Brazil. The authors found that WPL was more
attractive than NPV, wihout considering the land as revenue at the end of the period.
In our worst scenario (item 3.3.3.4.3, land prices decrease annually for the next 14
years), the results was similar. Despite increasing land prices , MAPITO showed
better return of investments in all price variations at the end of the cycle, while São
Paulo and Mato Grosso do Sul States were feasible only if the land price has had a
minimum increase of 8.9 and 2.8 % per state, respectively.
Despite the less attractive risk/return relation, the state of São Paulo still has
good oportunities to invest. In the worst viable scenario (Topic 3.3.3.3. Land
Expected Value ), the maximum accetable land price in the state was 3,518.82
R$.ha-1. For this price, investors can find properties in the municipalities of Registro
(Southwest) and Tupã (Central west) (IEA, 2012). However, desirable characteristics
(adequate size, near roads, good characteristics and infrastructure) should be
carefully analyzed in available lands for plantations.
MAPITO and Mato Grosso, conversely, have land available and the market
seems to be more dynamic than in São Paulo. Investors are able to find great land
opportunities in all over the theses states, even in the region of Três Marias in Mato
Grosso do Sul where the timberland market is currently more competitive due to the
pulp mill installed there.
120
3.4.2 Risk valuation
In the financial literature, project feasibility is not discussed without measuring
return of investments and risks. Deterministic analysis provides to investors only an
average opinion of the returns. Unpredictable changes, e.g., operational performance
or in the timber market, affect the final values and investors should be aware of
externalities and their impact on the expected return.
The results of deterministic analysis are discussed in several papers (BERGER
et al., 2011; PAIXÃO et al., 2006; SIREGAR; RACHMI, 2007); however, they are
useless if professionals do not take into account the risk involved in each cost and
revenue parameters. To attract investors’ attention, stochastic analysis should be
performed, where the relationship between risk and return is measured and thereby
adapted to the investors’ profile.
Our results allowed to make an analysis of the investors’ risk aversion.
Klemperer (1996) discussed the types of investors according to their risk aversion.
According to the author, there are three profiles of investors: 1) Risk-averse:
considers that the risk-revenue is worth less than a safer investment of the same
expected value. 2) Risk-neutral: the amount of variation in return makes no difference
to them and 3) Risk-seeker: for them, the possibility to make more money than
expected is more interesting than having a safer return.
Therefore, risk-averse investors would prefer to invest in the MAPITO region
rather than in São Paulo or Mato Grosso do Sul States despite the possibility to have
lower returns. The MAPITO region was the least risky region to invest. The standard
deviation was lower than other regions in all criteria. This fact is mainly linked to land
price and volume that showed the smallest range, 173.33 to 2,716.66 R$.ha-1 for land
price and 182 to 287 m3.ha-1 at the end of the seventh period. Risk seekers and risk
neutral profiles, on the other hand, would prefer to invest in São Paulo or Mato
Grosso do Sul, because of the greater likelihood to have higher returns. In the WLP,
considering the increase of land price criteria, investors can make 6,451.20 R$.ha-1 in
Mato Grosso do Sul and 10,881.06 R$.ha-1 in São Paulo States.
São Paulo presented by far riskiest project in all economic criteria among the
regions analyzed. The standard deviation had the highest value in the state. This is
linked mainly to the range of production levels at the end of the rotations (104 to 417
m3.ha-1) and the land price range (2,280.20 to 18,181.80 R$.ha-1).
121
The risk of failure of the project was reduced when we considered WLP criteria.
São Paulo presented the most drastic change, rising from 3.3 % in the NPV to 21.4
% considering a decrease in the land prices. Castro et al., 2007 found results that are
more attractive for the state of Minas Gerais (a traditional Eucalypt producer) in terms
of likelihood. The authors reported that 30 % of NPV in that state were higher than
zero in a Eucalypt project to produce charcoal. However, the authors used as
minimal acceptable rate of return of 8.75 % and fewer variables than we did in our
research. They used 5 variables and did not include land price variation.
3.5 Conclusion
In this chapter, we have presented an economic analysis of forest projects in
different regions in Brazil. We have found significant evidence for higher
attractiveness in forest projects in new agriculture frontier than in traditional regions.
The land price range is one of the main aspects to influence the attractiveness
of traditional regions. The traditional producing regions still have attractive areas to
establish new forest plantations; however, investors’ desirable characteristics
(reasonable size, price and site quality) should be investigated.
The risk analysis is essential to support the investors’ decision because
determinist methods give only a small fraction of the economic analysis. Moreover,
despite a careful study, a project is subject to some immeasurable risks such as
changes in the political and business environments.
Brazil’s territorial dimension favored the study to be applied in a macro analysis.
Institutional investors are looking for new regions and countries that do not have
tradition in forest projects. Analyzing forest projects in foreign countries demands
deeper investigation due to the distinct laws, taxes and business culture. However,
criteria for a project evaluation must reflect the attractiveness in countries, as
attractiveness among regions was reported in this research.
122
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APPENDIX
130
4.1 Survey
US South – Brazil Timberland Investment Questionnaire
This interview is designed to learn more about your investment practices in the U.S.
and Brazil as relevant. This research will provide general information about forest
investments that could be useful for investment benchmarking and to provide to
prospective investors. We have questions about your strategies and specific factors
that influence them. You do not need to answer any questions that you feel would
present a problem with proprietary business information, of course.
I. Introduction
1. Date
2. Name of Interviewee
3. Location (city/state)
___________________________________________
4. Email: _________________ 5. Tel: _____________________
II. Background Information
6. When did your company start making forest investments (specify year)?
a. In the USA? _______
b. In Brazil? _______
7. What are your company forest investment specializations—e.g., regions,
countries, species, etc.?
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8. How much forest land do you own or manage?
Type U.S. (ac) Brazil (ha)
Total
Planted Pine
Natural Pine
Hardwoods
Eucalyptus
With Conservation
Easements
9. What are the characteristics of your current investment?
Characteristic Units World U.S. Brazil
Total Assets of
Funds
Dollars
Number of Funds No.
Employees No.
Minimum Tract Size Ac.
10. What is your U.S. organization type?
a. _____C-Corporation
b. _____Limited Liability Corporation
c. _____ S-Corporation
d. _____ Other (specify) ____________________
11. What is your Brazil organization type?
a. _____ Limited Liability (Limitado)
b. _____ Anonymous Society (Sociedade Anônima)
c. _____ Limited Partnership with Share ( Limitada com Divisão de Ações)
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d. _____ General Partnership (Sociedade)
e. _____ Corporation (Corporação)
f. _____ Other (specify) _____________________
12. How did your company invest in Brazil?
a. _____ Acquiring an existing company
b. _____ Develop a partnership with a local company
c. _____ Establishing your own branch in Brazil
d. _____ Other (Specify) _____________________
13. What legal arrangements were required to start and operate business in Brazil?
III. Investment Characteristics
1. How do you choose your investments?
2. Do you prefer:
a. U.S. or international investments? Why?
b. Natural forests or plantations? Why?
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3. How important are the following country macroeconomic factors in your forest
investment decisions?
(Circle the level of importance that applies: 1=not important; 2=slightly important;
3=somewhat important; 4=quite important; 5=extremely important)
Characteristic
Not at all Somewhat Extremely
Important Important Important
Country GDP 1 2 3 4 5
GDP growth 1 2 3 4 5
Market size 1 2 3 4 5
Political risk 1 2 3 4 5
Personal risk 1 2 3 4 5
Trade 1 2 3 4 5
Other
(specify)
1 2 3 4 5
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4. How important are the following institutional factors in your forest investment
decisions?
(Circle the level of importance that applies: 1=not important; 2=slightly important;
3=somewhat important; 4=quite important; 5=extremely important)
Characteristic
Not at all Somewhat Extremely
Important Important Important
Infrastructure 1 2 3 4 5
Ease of doing business 1 2 3 4 5
Land ownership laws 1 2 3 4 5
Current land use 1 2 3 4 5
Land price 1 2 3 4 5
Land location 1 2 3 4 5
Access to domestic credit 1 2 3 4 5
Tax rates 1 2 3 4 5
Tax complexity 1 2 3 4 5
Other (specify) 1 2 3 4 5
5. How important are the following forest factors in your investment decisions?
(Circle the level of importance that applies: 1=not important; 2=slightly important;
3=somewhat important; 4=quite important; 5=extremely important)
Characteristic
Not at all Somewhat Extremely
Important Important Important
135
Timber growth rates 1 2 3 4 5
Timber markets 1 2 3 4 5
Investment returns 1 2 3 4 5
Investment risks 1 2 3 4 5
Technical capacity 1 2 3 4 5
Environmental laws 1 2 3 4 5
Social/community
relations
1 2 3 4 5
Forest certification 1 2 3 4 5
Incentives and
subsidies
1 2 3 4 5
Other (specify) 1 2 3 4 5
6. Which of the proceeding macroeconomic, institutional, and forest factors are most
important in making your investment decisions?
7. How does the importance of these macroeconomic, institutional, and forest factors
differ by country—in the U.S. vs. Brazil—or by region within a country in your
decisions?
8. What are the economic expectations and requirements for your current
investments?
Characteristic U.S. Brazil
Discount rate (%)
Annual rate of return expected (%)
Time to start a business (days)
Average tax rate on profits (%)
9. Do you have minimum timber growth rates expected by your country for
investments? If so, how much per area per year?
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IV. Investors
1. What type of investors do you have and what is their expected rate of return?
Type Share of Company’s
Land Investments
(%)
Expected Annual
Rate of Return (%)
Pension funds
Insurance companies
Financial institutions
Universities
Other: (specify)
2. What are the main reasons an investor chooses to make a forest investment?
3. Do investors rate of return expectations differ by country or within regions ofeach
country?
4. Do investors recognize differences among regions, species, markets, and seek
particular types of timber investments?
5. What are the main concerns of investors?
6. Do investors require forest certification, social and community programs,
environmental compliance, or sustainability rankings/assurance to make forest
investments? Which ones, and why?
7. What are the minimum requirements to become an investor in your
company?
8. How do investors become a client of your company?
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V. Concluding Thoughts
1. Have we missed any important factors that influence your timberland
investments in the U.S. and Brazil, and if so what are they and how are
they important?
2. Do you plan to expand or contract your timberland investments in the future?
Where?
3. Thank you very much for your participation in this survey.
138
4.2 Consent Document
North Carolina State University
INFORMED CONSENT FORM FOR RESEARCH
Project: Brazil–US Southern Appraisal and Market Assessment
Research Team:
Bruno Kanieski da Silva a
Luiz C.E. Rodriguezb
Fred Cubbagec
John Welker d
Chris Singleton e
a Master Student in Forest Resources at College of Agriculture Luiz de Queiroz -
University of São Paulo, Brazil.
b Professor at College of Agriculture Luiz de Queiroz - University of Sao Paulo, Brazil.
c Professor at Department of Forestry and Environmental Resources – North Carolina
State University, USA.
d Senior Vice President/ Director, Technical and Data Services of American Forest
Management, USA.
e Certified General Appraiser at American Forest Management, USA.
Some general features you should know about research studies
Your company is being invited to take part in a research study. Your company has
the right to choose not to participate or to stop participating at any time without
penalty. The purpose of this research is to gain a better understanding about
timberland investments in the Americas. It is not guaranteed to you any personal
benefits from being part of this study. This consent form provides details about the
139
research. If you do not understand something in this form, it is your right to ask the
researcher for clarification or further information. A copy of this consent form will be
provided for you.
Purpose of this study
This interview is part of a dissertation of the student Bruno Kanieski da Silva to obtain
the title of master at the University of Sao Paulo, Brazil, in cooperation with American
Forest Management Inc. and North Carolina State University. As part of the research
team, this project has as main advisor Professor Luiz C.E. Rodriguez from the
University of Sao Paulo, Professor Fred Cubbage from the North Carolina State
University, Chris Singleton and John Welker from American Forest Management.
The intention of this study is to understand the current status of forest investments in
Brazil and USA. In addition, this study will assess the actual barriers and future
expectations of forest investments.
Participation in this study
If your company agrees to participate in this study, you will be asked to answer some
questions about the characteristics of the forest asset managed by your company,
your understanding of actual and future opportunities and the expected returns of
investors. The complete process will take approximately 2 hours.
Benefits
Confidentiality
The information in these records will be kept confidential to the full extent allowed by
law. Data will be stored securely in paper form and on a single computer hard drive.
The original interview forms will be destroyed after the completion of the thesis, or in
two years at the most. No reference will be made in oral or written reports which
could link your company to this study.
Compensation
140
Your company will not receive any kind of payment for participating in this study.
Questions about this study
If there are any questions about this study or the procedures, you may contact the
researcher at any time:
Bruno Kanieski, at 1930 A Gion Street, Sumter, SC, 29150,
[email protected] or telephone 704-351-7865 or Fred Cubbage at
[email protected], or 919-515-7789.
Questions about your rights as a research participant
If the condition mentioned were not fallowed or your rights as a participant in
research have been violated during the course of this project, you may contact Deb
Paxton, Regulatory Compliance Administrator, Box 7514, NCSU Campus (919/515-
4514).
Consent to Participate
“I have read and understand the above information. I have received a copy of this
form. I agree to participate in this study with the understanding that I may choose to
stop participating at any time without penalty to which I am otherwise entitled.”
Subject's signature_______________________________________ Date
_________________
Investigator's signature__________________________________ Date
_________________
141
142
4.3 Institutional Review Board (IRB) approval
143
4.4 Commands in the software R
####### ECONOMIC, INSTITUTIONAL AND FOREST FACTOR ANALYSIS ######
# Variables #
##load the .csv file ##
mydata02 = read.csv(file="multivariada_entrevistados13.csv",sep= ",")
mydata02$NOME = NULL
mydata02
# Run the Packages "Ecodist"
# Correlation
cor.distance <- as.dist(1-((cor(mydata02))))
cd = cor.distance
# Dendrogram
hclust.cd = hclust (cd,"complete")
plot (hclust.cd)
144
4.5 Machinery fixed cost in the state of São Paulo.
Machine Initial Price R$(2012) Estimate Life(hours)* Annual Hours Estimate Life (years)
Grader 480,000.00 16000 400.00 40.00
Tractor 125 HP 110,000.00 12000 400.00 30.00
Tractor 85 HP 90,000.00 12000 400.00 30.00
Implements Initial Price R$(2012) Estimate Life(hours)* Annual Hours Estimate Life (years)
Forest Subsoiling (Heavy duty disk) 27,000.00 2000 400.00 5.00
Limestone Spreader 16,800.00 2000 400.00 5.00
Reservoir (6000 liters) 7,900.00
2000 400.00 5.00
Reservoir (500 liters) 4,800.00 2000 400.00 5.00
Seedling Supporter 5,000.00 3000 400.00 7.50
Fertilizer Spreader 7,500.00 1200 400.00 3.00
Mower 13,500.00 1200 400.00 3.00
145
4.5 Machinery fixed cost in the state of São Paulo.
Machine Interest
Rate
Remaining Factor Value
Salvage Price Depreciation
Capital recovery factor
Capital recovery (R$ per year) Source
Grader 11% 17% 81,600.00 398,400.00 0.115 55,101.78 Agrianual 2013
Tractor 125 HP 11% 23% 25,300.00 84,700.00 0.118 12,882.91 Agrianual 2013
Tractor 85 HP 11% 20% 18,000.00 72,000.00 0.118 10,553.25 Agrianual 2013
Implements Interest
Rate
Remaining Factor Value
Salvage Price Depreciation
Capital recovery factor
Capital recovery (R$ per year) Source
Forest Subsoiling (Heavy duty disk) 11% 26%
7,020.00 19,980.00 0.273
6,250.44 Agrianual 2013
Limestone Spreader 11% 29% 4,872.00 11,928.00 0.273 3,808.80 Agrianual 2013 Reservoir (6000 liters) 11% 20%
1,580.00 6,320.00 0.273
1,904.42 http://www.mercadomaquinas.com.br/
Reservoir (500 liters) 11% 20%
960.00 3,840.00 0.273
1,157.11 http://www.mfrural.com.br/
Seedling Supporter 11% 16% 800.00 4,200.00
0.205 952.05
http://www.mfrural.com.br/
Fertilizer Spreader 11% 29% 2,175.00 5,325.00
0.412 2,439.20
http://www.mfrural.com.br/
Mower 11% 21% 2,835.00 10,665.00
0.412 4,712.62
http://www.mercadomaquinas.com.br/
* Source : Agricultural Machinery Management Data - Stands - 2003
146
4.5 Machinery fixed cost in the state of São Paulo.
Machine TIH (Taxes, Insurance and Housing)
Total Fixed Cost R$ per year Fixed cost (R$/ha/hour)
Grader 4,800.00 59,901.78 149.75
Tractor 125 HP 1,100.00 13,982.91 34.96
Tractor 85 HP 900.00 11,453.25 28.63
Implements TIH (Taxes, Insurance and Housing)
Total Fixed Cost R$ per year Fixed cost (R$/ha/hour)
Forest Subsoiling (Heavy duty disk) 270.00 6,520.44 16.30
Limestone Spreader 168.00 3,976.80 9.94
Reservoir (6000 liters) 79.00 1,983.42 4.96
Reservoir (500 liters) 48.00 1,205.11 3.01
Seedling Supporter 50.00 1,002.05 2.51
Fertilizer Spreader 75.00 2,514.20 6.29
Mower 135.00 4,847.62 12.12
147
4.6 Machinery variable cost in the state of São Paulo.
Machine Hoursepower Kw Consumption Factor
(Diesel)* Average Diesel fuel consumption (L/hour)
Grader 190.00 141.68 0.163 23.09
Tractor 125 HP 125.00 93.21 0.163 15.19
Tractor 85 HP 85.00 63.38 0.163 10.33
Implements Hoursepower Kw Consumption Factor
(Diesel)* Average Diesel fuel consumption (L/hour)
Forest Subsoiling (Heavy duty disk)
Limestone Spreader
Reservoir (6000 liters)
Reservoir (500 liters)
Seedling Supporter
Fertilizer Spreader
Mower
148
4.6 Machinery variable cost in the state of São Paulo
Machine Diesel Price (R$/L) Average fuel cost per hour
(R$/hour) Lubrication ** Repair
Factor*** Repair cost per
hour
Total Variable Cost
(R$/ha/hour)
Grader 2.00 46.19 6.93 100% 30.00 83.12
Tractor 125 HP 2.00 30.39 4.56 80% 7.33 42.28
Tractor 85 HP 2.00 20.66 3.10 100% 7.50 31.26
Machine Diesel Price (R$/L) Average fuel cost per hour
(R$/hour) Lubrication ** Repair
Factor*** Repair cost per
hour
Total Variable Cost
(R$/ha/hour)
Forest Subsoiling (Heavy duty disk) 60% 8.10 8.10
Limestone Spreader 80% 0.00
Reservoir (6000 liters) 50% 1.98 1.98
Reservoir (500 liters) 50% 1.20 1.20
Seedling Supporter 50% 0.83 0.83
Fertilizer Spreader 80% 5.00 5.00
Mower 150% 16.88 16.88
*Book - Conservação e Cultivo de solos para plantações florestais. Capítulo 13.
**Paper - Estimating Farm Machinery Costs
*** Source : Agricultural Machinery Management Data - Stands - 2003 (total R&M Cost)
149
4.7 Machinery total cost in the state of São Paulo
Machine Total Cost (R$/hour)
Grader 232.87
Tractor 125 HP 77.24
Tractor 85 HP 59.90
Implements Total Cost (R$/ha/hour)
Forest Subsoiling (Heavy duty disk) 24.40
Limestone Spreader 9.94
Reservoir (6000 liters) 6.93
Reservoir (500 liters) 4.21
Seedling Supporter 3.34
Fertilizer Spreader 11.29
Mower 28.99
150
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4.8 Inflation Correction
Appendix 4.8 – Inflation Correction
Year IGP - DI (%) IGP-DI ( Base year 2012) % Index Factor (2012)
2002 26% 54% 185.93%
2003 8% 58% 172.68%
2004 12% 65% 154.00%
2005 1% 66% 152.15%
2006 4% 68% 146.59%
2007 8% 74% 135.87%
2008 9% 80% 124.54%
2009 -1% 79% 126.34%
2010 11% 88% 113.52%
2011 5% 93% 108.10%
2012 8% 100% 100.00%
Source: Fundação Getúlio Vargas